COGNITIVE NEUROSCIENCE THE BIOLOGY OF THE MIND Fourth Edition - PDFCOFFEE.COM (2024)

COGNITIVE NEUROSCIENCE THE BIOLOGY OF THE MIND

Fourth Edition

Michael S. Gazzaniga, Richard B. Ivry, and George R. Mangun

Developing Physically | i

FOURTH EDITION

Cognitive Neuroscience The Biology of the Mind MICHAEL S. GAZZANIGA University of California, Santa Barbara

RICHARD B. IVRY University of California, Berkeley

GEORGE R. MANGUN University of California, Davis

With special appreciation for the Fourth Edition to Rebecca A. Gazzaniga, M.D.

b

W. W. Norton & Company has been independent since its founding in 1923, when William Warder Norton and Mary D. Herter Norton first published lectures delivered at the People’s Institute, the adult education division of New York City’s Cooper Union. The firm soon expanded its program beyond the Institute, publishing books by celebrated academics from America and abroad. By midcentury, the two major pillars of Norton’s publishing program—trade books and college texts—were firmly established. In the 1950s, the Norton family transferred control of the company to its employees, and today—with a staff of four hundred and a comparable number of trade, college, and professional titles published each year—W. W. Norton & Company stands as the largest and oldest publishing house owned wholly by its employees. Editors: Aaron Javsicas and Sheri Snavely Development Editor: Michael Zierler Project Editor: Diane Cipollone Electronic Media Editor: Callinda Taylor Editorial Assistant: Shira Averbuch Marketing Manager, Psychology: Lauren Winkler Production Manager: Eric Pier-Hocking Photo Editor: Stephanie Romeo Photo Researcher: Elyse Rieder Permissions Manager: Megan Jackson Permissions Clearing: Bethany Salminen Art Director: Rubina Yeh Designer: Lisa Buckley Composition: TSI Graphics Manufacturing: Quad Graphics The text of this book is composed in Epic with the display set in Mr Eaves San, Mr Eaves XL San, Franklin Gothic Std. Copyright © 2014, 2009, 2002, 1998 by Michael S. Gazzaniga, Richard B. Ivry, and George R. Mangun All rights reserved. Printed in the United States of America. Library of Congress Cataloging-in-Publication Data. Gazzaniga, Michael S. Cognitive neuroscience : the biology of the mind / Michael S. Gazzaniga, University of California, Santa Barbara; Richard B. Ivry, University of California, Berkeley; George R. Mangun, University of California, Davis. -- Fourth edition. pages cm Includes bibliographical references and index. ISBN 978-0-393-91348-4 (hardcover) 1. Cognitive neuroscience. I. Ivry, Richard B. II. Mangun, G. R. (George Ronald), 1956- III. Title. QP360.5.G39 2013 612.8’233--dc23 2013027471 W. W. Norton & Company, Inc., 500 Fifth Avenue, New York, NY 10110-0017 wwnorton.com W. W. Norton & Company Ltd., Castle House, 75/76 Wells Street, London W1T 3QT 1 2 3 4 5 6 7 8 9 0

For Lilly, Emmy, Garth, Dante, and Rebecca M.S.G.

For Henry and Sam R.B.I.

For Nicholas and Alexander G.R.M.

Brief Overview PART I 1

Background and Methods A Brief History of Cognitive Neuroscience

2

2 Structure and Function of the Nervous System 22 3 Methods of Cognitive Neuroscience PART II

Core Processes

4 Hemispheric Specialization 5 Sensation and Perception 6 Object Recognition 7 Attention 8 Action

162

218

326 378

10 Emotion

424

11 Language

12

120

272

9 Memory

PART III

70

468

Control Processes Cognitive Control

13 Social Cognition

506 558

14 Consciousness, Free Will, and the Law

604

Contents Boxes xii Preface xiii Acknowledgments

PART I

xv

Background and Methods

1 A Brief History of Cognitive Neuroscience

2

A Historical Perspective 4 The Brain Story 5 The Psychological Story 10 The Instruments of Neuroscience 14 The Electroencephalograph 14 Measuring Blood Flow in the Brain 15 Computerized Axial Tomography 15 Positron Emission Tomography and Radioactive Tracers 16 Magnetic Resonance Imaging 17 Functional Magnetic Resonance Imaging 17 The Book in Your Hands 19

2 Structure and Function of the Nervous System

22

The Structure of Neurons 24 Neuronal Signaling 27 The Membrane Potential 27 The Action Potential 30 Synaptic Transmission 32 Chemical Transmission 32 Neurotransmitters 33 Inactivation of Neurotransmitters after Release 34 Electrical Transmission 35 The Role of Glial Cells 35 The Bigger Picture 37

Overview of Nervous System Structure 37 The Autonomic Nervous System 38 The Central Nervous System 38 A Guided Tour of the Brain 40 The Spinal Cord 40 The Brainstem: Medulla, Pons, Cerebellum, and Midbrain 43 The Diencephalon: Thalamus and Hypothalamus 45 The Telencephalon: Limbic System, Basal Ganglia, and Cerebral Cortex 47 The Cerebral Cortex 49 Dividing the Cortex Anatomically 50 Dividing the Cortex Cytoarchitectonically 51 Functional Divisions of the Cortex 53 Development of the Nervous System 60 Overview of Gross Development 60 Birth of New Neurons Throughout Life 64 The Baby Brain: Ready to Rock ’n’ Roll? 66

3 Methods of Cognitive Neuroscience

70

Cognitive Psychology and Behavioral Methods 74 Ferreting Out Mental Representations and Transformations 74 Constraints on Information Processing 78 Studying the Damaged Brain 78 Causes of Neurological Dysfunction 79 Studying Brain–Behavior Relationships Following Neural Disruption 83 Functional Neurosurgery: Intervention to Alter or Restore Brain Function 86 v

vi | Contents

Methods to Perturb Neural Function 86 Pharmacology 87 Transcranial Magnetic Stimulation 88 Transcranial Direct Current Stimulation 89 Genetic Manipulations 89

PART II

Structural Analysis of the Brain 91 Computed Tomography 91 Magnetic Resonance Imaging 92 Diffusion Tensor Imaging 93 Methods for the Study of Neural Function 95 Single-Cell Recording in Animals 95 Single-Cell Recordings in Humans 98 Electroencephalography 98 Event-Related Potential 100 Magnetoencephalography 102 Electrocortogram 102 The Marriage of Function and Structure: Neuroimaging 104 Positron Emission Tomography 105 Functional Magnetic Resonance Imaging 107 Limitations of PET and fMRI 110 Brain Graphs 110 Computer Modeling 111 Representations in Computer Models 113 Models Lead to Testable Predictions 113 Converging Methods 114

Core Processes

4 Hemispheric Specialization

120

Anatomy of the Hemispheres 125 Anatomical Correlates of Hemispheric Specialization 125 Function of the Corpus Callosum 129 Splitting the Brain: Cortical Disconnection 133 The Surgery 133 Methodological Considerations in Studying Split-Brain Patients 134 Functional Consequences of the Split-Brain Procedure 135 Hemispheric Specialization 136 Evidence From Split-Brain Patients 136 Theory of Mind 145 The Interpreter 146 Evidence From Patients With Unilateral Cortical Lesions 149 Evidence From the Normal Brain 150 The Evolutionary Basis of Hemispheric Specialization 153

Hemispheric Specialization in Nonhumans 153 Modularity 154 Hemispheric Specialization: A Dichotomy in Function or Stylishly Different? 155 Is There a Connection Between Handedness and Left-Hemisphere Language Dominance? 156 Split-Brain Research as a Window into Conscious Experience 159

5 Sensation and Perception

162

Senses, Sensation, and Perception 164 Sensation: Early Perceptual Processing 164 Shared Processing From Acquisition to Anatomy 164 Receptors Share Responses to Stimuli 165 Audition 167 Neural Pathways of Audition 168 Computational Goals in Audition 170

Contents | vii

Olfaction 172 Neural Pathways of Olfaction 173 The Role of Sniffing in Olfactory Perception 174 One Nose, Two Odors 175 Gustation 176 Neural Pathways of Gustation 176 Gustatory Processing 178 Somatosensation 179 Neural Pathways of Somatosensation 179 Somatosensory Processing 180 Plasticity in the Somatosensory Cortex 181 Mechanisms of Cortical Plasticity 184 Vision 184 Neural Pathways of Vision 184 Cortical Visual Areas 187 From Sensation to Perception 197 Where Are Percepts Formed? 197 Individual Differences in Perception 200 Deficits in Visual Perception 201 Deficits in Color Perception: Achromatopsia 201 Deficits in Motion Perception: Akinetopsia 203 Perception Without a Visual Cortex 206 Multimodal Perception: I See What You’reSayin’ 207 Multimodal Processing in the Brain 208 Errors in Multimodal Processing: Synesthesia 211 Perceptual Reorganization 213

6 Object Recognition

218

Principles of Object Recognition 220 Multiple Pathways for Visual Perception 222 The What and Where Pathways 224 Representational Differences Between the Dorsal and Ventral Streams 224 Perception for Identification Versus Perception for Action 225 Computational Problems in Object Recognition 228 Variability in Sensory Information 230 View-Dependent Versus View-Invariant Recognition 231 Shape Encoding 232 Grandmother Cells and Ensemble Coding 233 Summary of Computational Problems 236

Failures in Object Recognition: The Big Picture 236 Apperceptive Agnosia 237 Integrative Agnosia 239 Associative Agnosia 240 Category Specificity in Agnosia: The Devil Is in the Details 241 Animate Versus Inanimate? 241 Organizational Theories of Category Specificity 243 Prosopagnosia Is a Failure to Recognize Faces 246 Processing Faces: Are Faces Special? 246 Regions of the Brain Involved in Face Recognition 248 Parts and Wholes in Visual Perception 253 Faces Are Processed in a Holistic Manner 255 Does the Visual System Contain Other Category-Specific Systems? 258 Mind Reading 261 Encoding and Decoding Brain Signals 261 Statistical Pattern Recognition 263 A Look Into the Future of Mind Reading 266

viii | Contents

Attention 306 Object Attention 308 Review of Attention and Perceptual Selection Mechanisms 309 Attentional Control Networks 311 Dorsal Attention Network: Frontoparietal Attention System 313 Ventral Right Attention Network 318 Subcortical Components of Attention Control Networks 319 Review of Attentional Control Networks 322

8 Action

7 Attention

272

The Anatomy of Attention 275 The Neuropsychology of Attention 275 Neglect 276 Neuropsychological Tests of Neglect 277 Extinction 278 Comparing Neglect and Bálint’sSyndrome 279 Models of Attention 280 Hermann von Helmholtz and Covert Attention 280 The Cocktail Party Effect 281 Early Versus Late Selection Models 283 Quantifying the Role of Attention in Perception 283 Neural Mechanisms of Attention and Perceptual Selection 286 Voluntary Spatial Attention 286 Reflexive Spatial Attention 295 Visual Search 297 Feature Attention 301 Interplay Between Spatial and Feature

326

The Anatomy and Control of Motor Structures 329 Muscles, Motor Neurons, and the Spinal Cord 330 Subcortical Motor Structures 332 Cortical Regions Involved in Motor Control 334 Computational Issues in Motor Control 337 Central Pattern Generators 337 Central Representation of Movement Plans 338 Hierarchical Representation of Action Sequences 340 Physiological Analysis of Motor Pathways 342 Neural Coding of Movement 342 Alternative Perspectives on Neural Representation of Movement 343 Goal Selection and Action Planning 346 Action Goals and Movement Plans 347 Representational Variation Across Motor Areas of the Cortex 348 The Brain–Machine Interface 352 Early Work on the Brain–Machine Interface 352 Making Brain–Machine Interface Systems Stable 353 Movement Initiation and the Basal Ganglia 356 The Basal Ganglia as a Gatekeeper 357 Disorders of the Basal Ganglia 358 Action Understanding and Mirror Neurons 363 Learning and Performing New Skills 366 Shift in Cortical Control with Learning 366 Adaptive Learning Through Sensory Feedback 367 Neural Mechanisms of Adaptation 368 Forward Models: Using Sensorimotor Predictions for Motor Control and Learning 371 Experts 373

Contents | ix

9 Memory

378

The Anatomy of Memory 381 Memory Deficits: Amnesia 382 Brain Surgery and Memory Loss 383 Recent Studies on Memory Loss 384 Mechanisms of Memory 384 Short-Term Forms of Memory 384 Long-Term Forms of Memory 389 The Medial Temporal Lobe Memory System 394 Evidence From Amnesia 394 Evidence From Animals With Medial Temporal Lobe Lesions 397 Imaging Human Memory 402 Encoding and the Hippocampus 402 Retrieval and the Hippocampus 404 Recognition, Familiarity, and the Medial Temporal Lobe 404 Encoding, Retrieval, and the Frontal Cortex 410 Retrieval and the Parietal Cortex 410 Memory Consolidation 413 The Hippocampus and Consolidation 413 The Lateral Anterior Temporal Lobe and Consolidation 414 Cellular Basis of Learning and Memory 415 Long-Term Potentiation and the Hippocampus 416 Long-Term Potentiation and Memory Performance 418

10 Emotion

424

What Is an Emotion? 427 Neural Systems Involved in Emotion Processing 428 Early Concepts: The Limbic System as the Emotional Brain 428 Emerging Concepts of Emotional Networks 429 Categorizing Emotions 430 Basic Emotions 431 Complex Emotions 432 Dimensions of Emotion 433 Theories of Emotion Generation 434 James–Lange Theory 434 Cannon–Bard Theory 435 Appraisal Theory 435 Singer–Schachter Theory: CognitiveInterpretation of Arousal 435 Constructivist Theories 436

Evolutionary Psychology Approach 436 LeDoux’s High Road and Low Road 436 The Amygdala 437 Interactions Between Emotion and Other Cognitive Processes 438 The Influence of Emotion on Learning 439 Implicit Emotional Learning 439 Explicit Emotional Learning 443 The Influence of Emotion on Perception and Attention 446 Emotion and Decision Making 447 Emotion and Social Stimuli 449 Get A Grip! Cognitive Control of Emotion 455 Other Areas, Other Emotions 459 The Insular Cortex 459 Disgust 460 Happiness 461 Love 461 Unique Systems, Common Components 464

11 Language

468

The Anatomy of Language 471 Brain Damage and Language Deficits 472 Broca’s Aphasia 472 Wernicke’s Aphasia 473 Conduction Aphasia 474 The Fundamentals of Language in the Human Brain 475 Words and the Representation of Their Meaning 475 Models of the Mental Lexicon 476 Neural Substrates of the Mental Lexicon 477 Language Comprehension 480 Perceptual Analyses of the Linguistic Input 480

x | Contents

Spoken Input: Understanding Speech 481 Written Input: Reading Words 484 The Role of Context in Word Recognition 489 Integration of Words in Sentences 490 Semantic Processing and the N400 Wave 490 Syntactic Processing and the P600 Wave 491

PART III

Neural Models of Language Comprehension 495 Networks of the Left-Hemisphere Language System 496 Neural Models of Speech Production 496 Evolution of Language 500 Shared Intentionality 500

Control Processes

12 Cognitive Control

506

What Is Cognitive Control? 508 The Anatomy Behind Cognitive Control 509 Subdivisions of the Frontal Lobes 509 Networks Underlying Cognitive Control 509 Cognitive Control Deficits 510 Goal-Oriented Behavior 511 Cognitive Control Requires Working Memory 512 Prefrontal Cortex Is Necessary for Working Memory but Not Associative Memory 512 Physiological Correlates of Working Memory 513 Processing Differences Across Prefrontal Cortex 517 Hierarchical Organization of Prefrontal Cortex 519 Decision Making 520 Is It Worth It? Value and Decision Making 521

Components of Value 522 Representation of Value 522 More Than One Type of Decision System? 525 Dopamine Activity and Reward Processing 526 Alternative Views of Dopamine Activity 530 Goal Planning 532 Cognitive Control Is Necessary for Planning and Staying on Goal 534 Retrieval and Selection of Task-Relevant Information 535 Task Switching 538 Goal-Based Cognitive Control 539 Goal Representation and the Inhibition and Enhancement of Working Memory Representations 539 Prefrontal Cortex and Modulation of Processing 543 Inhibiting Activation of Long-Term Memory 545 Inhibition of Action 545 Ensuring That Goal-Oriented Behaviors Succeed 549 The Medial Frontal Cortex as a Monitoring System 550 How Does Medial Frontal Cortex Monitor Processing in Cognitive Control Networks? 550

13 Social Cognition

558

Anatomical Substrates of Social Cognition 561 Deficits 561 Socrates’ Imperative: Know Thyself 563 Self-Referential Processing 563 Self-Descriptive Personality Traits 567 Self-Reference as a Baseline Mode of Brain Function 568

Contents | xi

Self-Perception as a Motivated Process 570 Predicting Our Future Mental State 572 Theory of Mind: Understanding the Mental States of Others 573 Developmental Milestones 573 Mechanisms for Inferring Other People’s Thoughts 575 Neural Correlates of Mental State Attribution 580 Autism as a Window on the Role of Mental State Attribution 586 Social Knowledge 592 Representations of Social Knowledge 593 Using Social Knowledge to Make Decisions 595 Neuroeconomics 596 Moral Decisions 598

14 Consciousness, Free Will, and theLaw

604

Anatomical Orientation 607 The Brainstem 607 The Thalamus 608 The Cerebral Cortex 608 Consciousness 608 Conscious Versus Unconscious Processing and the Access of Information 610 The Extent of Subconscious Processing 612 Gaining Access to Consciousness 615 Sentience 618 Neurons, Neuronal Groups, and Conscious Experience 618 The Emergence of the Brain Interpreter in the Human Species 620 Left- and Right-Hemisphere Consciousness 621 Is Consciousness a Uniquely Human Experience? 622 Abandoning the Concept of Free Will 623 Determinism and Physics 624 Chaos 625 Quantum Theory 625 Emergence 626 Multiple Realizability 627 Can Mental States Affect Brain Processing? 628 The Layer Beyond the Brain 631

The Law 631 Responsibility 632 Guilty—Now What? 636 Born to Judge 637 What’s a Judge to Do? 638 Crime and No Punishment? 639 Taming the Wild Beast 639

Glossary G-1 References R-1 Abbreviations Credits C-1 Index

I-1

A-1

Boxes How the Brain Works

Milestones in Cognitive Neuroscience

The Chambers of the Mind 42

Interlude 11

Cortical Topography

Pioneers in the Visual Cortex

55

Billions and Billions: Brain Size, Complexity, and Human Cognition 58

191

Psychiatric Disorders and the Frontal Lobes 564

Blood Supply and the Brain 61 Interhemispheric Communication: Cooperation or Competition? 131 To Approach or Withdraw: The Cerebral Tug-of-War 157 When the Receptors No Longer Function: The Retinal Implant 188

The Cognitive Neuroscientist’s Toolkit Navigating the Brain 41 Understanding the Data From the Letter-Matching Task 75 Study Design: Single and Double Dissociations 84

Now You See It, Now You Don’t 223

Correlation and Causation: Brain Size and PTSD

Auditory Agnosia

Raster Plots 96

238

92

Visual Perception, Imagery, and Memory 242

ERP Recordings 100

Autism and Face Perception 247

Analyzing Brain Scans 112

Attention, Arousal, and Experimental Design 286

Contributions of the Basal Ganglia to Learning and Cognition 360

Shocking Studies of Attention

298

Spikes, Synchrony, and Attention 310

Dimensions of Emotional Style 456

Where Is It? Assessing Location Through Perception and Action 339

Stimulation Mapping of the Human Brain 488

Patting Your Head While Rubbing Your Stomach 350

Neuroethics: An Emerging Field 600

Short-Term Memory Capacity 386 False Memories and the Medial Temporal Lobes 409 Stress and Memory

415

Sleep and Memory Consolidation 416 Genetic Components of Language

503

Working Memory, Learning, and Intelligence 514 Thinking Outside the (Match)Box

536

Multitasking 540 Understanding Substance Abuse: Insights from the Study of Cognitive Control 548 Eyewitness Testimony 633

xii

Aphasia and Electrophysiology

494

Preface Welcome to the fourth edition! When cognitive neuroscience emerged in the late 1970’s, it remained to be seen if this new field would have “legs.” Today, the answer is clear: the field has blossomed in spectacular fashion. Cognitive neuroscience is well represented at all research universities, providing researchers and graduate students with the tools and opportunities to develop the interdisciplinary research programs that are the mainstay of the field. Multiple journals, some designed to cover the entire field, and others specialized for particular methodologies or research themes, have been launched to provide venues to report the latest findings. The number of papers rises at an exponential rate. The annual meeting of the Cognitive Neuroscience Society has also flourished. While 400 pilgrims attended the first meeting in 1993, the 20th anniversary meeting in 2013 was attended by almost 2000 people. The fundamental challenge we faced in laying the groundwork for our early editions was to determine the basic principles that make cognitive neuroscience distinct from physiological psychology, neuroscience, cognitive psychology, or neuropsychology. It is now obvious that cognitive neuroscience overlaps with, and synthesizes, these disciplinary approaches as researchers aim to understand the neural bases of cognition. In addition, however, cognitive neuroscience is increasingly informing and informed by disciplines outside the mind-brain sciences, as exemplified by our new Chapter 14: “Consciousness, Free Will, and the Law” As in previous editions, we continue to seek a balance between psychological theory, with its focus on the mind, and the neuropsychological and neuroscientific evidence about the brain that informs this theory. We make liberal use of patient case studies to illustrate essential points and observations that provide keys to understanding the architecture of cognition, rather than providing an exhaustive description of brain disorders. In every section, we strive to include the most current information and theoretical views, supported by evidence from the cutting-edge technology that is such an important part of cognitive neuroscience. In contrast to purely cognitive or neuropsychological approaches, this text emphasizes the convergence of evidence that is a crucial aspect of any science, particularly studies of higher mental function. We also provide examples of research using computational techniques to complete the story.

Teaching students to think and ask questions like cognitive neuroscientists is a major goal of our text. As cognitive neuroscientists, we examine mind–brain relationships with a wide range of techniques, such as functional and structural brain imaging, neurophysiological recording in animals, human EEG and MEG recording, brain stimulation methods, and analysis of syndromes resulting from brain damage. We highlight the strengths and weaknesses of these methods to demonstrate how these techniques must be used in a complementary manner. We want our readers to learn what questions to ask, how to choose the tools and design experiments to answer these questions, and how to evaluate and interpret the results of those experiments. Despite the amazing progress of the neurosciences, the brain remains a great mystery, with each insight inspiring new questions. For this reason, we have not used a declarative style of writing throughout the book. Instead, we tend to present results that can be interpreted in more than one way, helping the reader to recognize that there are possible alternative interpretations. Since the first edition, there have been many major developments, both methodological and theoretical. There has been an explosion of brain imaging studies—almost 1,500 a year for the last decade. New technologies, such as transcranial magnetic stimulation, diffusion tensor imaging and optogenetics have been added to the arsenal of the cognitive neuroscientist. New links to genetics, comparative anatomy, computation and robotics have emerged. Parsing all of these studies and deciding which ones should be included has been a major challenge for us. We firmly believe that technology is a cornerstone of scientific advancement. As such, we have felt it essential to capture the cutting-edge trends in the field, while keeping in mind that this is an undergraduate survey text that needs to be completed in a quarter or semester. The first three editions have provided compelling evidence that our efforts have led to a highly useful text for undergraduates taking their first course in cognitive neuroscience, as well as a concise reference volume for graduate students and researchers. Over 400 colleges and universities worldwide have adopted the text. Moreover, instructors tell us that in addition to our interdisciplinary approach, they like that our book has a strong narrative voice and offers a manageable number of chapters to teach in a one-semester survey course. xiii

xiv | Preface

Still, we have had to do some pruning for the 4th edition in order to present both the foundations of cognitive neuroscience and the latest the field has to offer; in general, we have opted to take a leaner approach than in previous editions, providing the necessary updates on new developments while streamlining the descriptions of experimental results. Inspired by feedback from our adopters, we have also made some changes to make the text even more user friendly. Highlights of the fourth edition include the following: ■

All the chapters have been rewritten. In order to add new findings but maintain a reasonable sized text, we had to trim out some of the older material and streamline our presentations. Careful attention has been paid to the chapter’s heading and subheading structure to provide a roadmap to the essential themes of the chapters. The illustrations have been redrawn. The stunning new art program is designed to facilitate student understanding, and now includes a “hand-pointer” feature that draws students’ attention to the most important figure elements. We have added an “anatomical orientation” figure at the beginning of each chapter to orient students to the brain regions that will be major players throughout the chapter. Key points to remember have been interspersed after major sections throughout the text instead of being stacked at the end of the chapter. The chapters on cellular mechanisms and neuroanatomy have been combined, providing a concise presentation of the basic concepts that are most essential for cognitive neuroscience. The focus of the field is more at the systems level of analysis, and this has led us to leave the more detailed study of cellular and molecular topics to texts dedicated to these levels of analysis. We have eliminated the chapter on the evolutionary perspective and instead have sprinkled discussions of this topic throughout the text. An extensive section on decision-making has been added to the cognitive control chapter. The chapter on emotion has been expanded and includes extensive discussion of the fine interplay between affective and cognitive neurosciences. We have added a new chapter that tackles the important, yet elusive problem of consciousness, taking on issues such as free will and how cognitive neuroscience can have practical applications for informing public policy and the law.

The new edition also offers an even more generous suite of instructor ancillaries: ■

Lecture PowerPoints, new to this edition, feature text and images as well as instructor-only lecture notes and suggestions. Art PowerPoints and JPEGs provide all the art and tables from the book in easily adaptable formats. The Test Bank for Cognitive Neuroscience, Fourth Edition, has been developed using the Norton Assessment Guidelines. Each chapter of the Test Bank includes five question types classified according to the first five levels of Bloom’s taxonomy of knowledge types. The Studying the Mind DVD includes exclusive Norton interviews with leading cognitive neuroscience researchers on key aspects of how we study the human mind. The Cognitive Neuroscience Patient Interviews DVD presents original footage of interviews with patients suffering from a variety of cognitive and neurological disorders, and bring to life the cognitive models, concepts, and research methodologies discussed in the text. Several new videos have been added for the fourth edition.

As with each edition, this book has required a laborious interactive effort among the three of us, along with extensive discussions with our colleagues, our students, and our reviewers. The product has benefited immeasurably from these interactions. Of course we are ready to modify and improve any and all of our work. In our earlier editions, we asked readers to contact us with suggestions and questions, and we do so again. We live in an age where interaction is swift and easy. We are to be found as follows: [emailprotected]; [emailprotected]; [emailprotected]. Good reading and learning!

Acknowledgments Once again, we are indebted to a number of people. First and foremost we would like to thank Rebecca A. Gazzaniga, M.D. for her extensive and savvy editing of the Fourth Edition. She mastered every chapter, with an eye to make sure the story was clear and engaging. We could not have completed this edition without her. We are also especially grateful to Tamara Y. Swaab, Ph.D. (University of California, Davis), for the language chapter in this and prior editions, Michael B. Miller, Ph.D. (University of California, Santa Barbara), for contributions to the chapter on hemispheric lateralization, Stephanie Cacioppo, Ph.D. (University of Chicago), for contributions to the chapter on emotion, and Jason Mitchell, Ph.D. (Harvard University), for contributions to the social cognition chapter. For answering miscellaneous questions that cropped up in the methods chapter we would like to tip our hats to Scott Grafton (University of California, Santa Barbara) and Danielle Bassett. For work on the previous editions that continues to play an active part in this new edition we thank again Megan Steven (Dartmouth College) for her writing skills, Jeff Hutsler (University of Nevada, Reno) and Leah Krubitzer (University of California, Davis) for evolutionary perspectives, Jennifer Beer (University of Texas, Austin) for insights on social cognition, and Liz Phelps for her work on emotion. Tim Justus (Pitzer College), Chadd Funk, Adam Riggal, Karl Doron, Kristin McAdams, and Todd Heatherton (Dartmouth College) who are all to be thanked for sharing their advice and wisdom and for helping along the way. We thank Frank Forney for his art in the previous editions, and Echo Medical Media for the new art in this edition. We also thank our many colleagues who provided original artwork or scientific figures. We would also like to thank our readers Annik Carson and Mette ClausenBruun who took the time to point out typos in our previous edition, to anatomist Carlos Avendaño, who alerted us to some anatomical errors, and to Sophie van Roijen, who suggested the very good idea of adding an index of abbreviations. Several instructors took time from their busy schedules to review our previous edition and make suggestions for this edition. We thank Joy Geng, University of California, Davis; Brian Gonsalves, University of Illinois; Roger Knowles, Drew University; Sam McClure, Stanford University; John McDonald, Simon Fraser University; Kath-

leen Taylor, Columbia University; and Katherine Turner, San Diego State University. In addition, we are indebted to many scientists and personal friends. Writing a textbook is a major commitment of time, intellect, and affect! Those who helped significantly are noted below. Some reviewed our words and critiqued our thoughts. Others allowed us to interview them. To all we owe our deep gratitude and thanks. Eyal Aharoni, Rand University; David G. Amaral, University of California, Davis; Franklin R. Amthor, University of Alabama, Birmingham; Michael Anderson, St. Andrews University; Adam Aron, University of California, San Diego; Ignacio Badiola, Florida International University; David Badre, Brown University; Juliana Baldo, VA Medical Center, Martinez, California; Gary Banker, Oregon Health Sciences University; Horace Barlow, Cambridge University; Kathleen Baynes, University of California, Davis; N. P. Bechtereva, Russian Academy of Science; Mark Beeman, Northwestern University; Marlene Behrmann, Carnegie Mellon University; Robert S. Blumenfeld, University of California, Davis; Elizabeth Brannon, Duke University; Rainer Breitling, San Diego State University; Silvia Bunge, University of California, Berkeley; Valerie Clark, University of California, Davis; Clay Clayworth, VA Medical Center, Martinez, California; Asher Cohen, Hebrew University; Jonathan Cohen, Princeton University; Roshan Cools, Radboud University; J. M. Coquery, Université des Sciences et Technologies de Lille; Michael Corballis, University Auckland; Paul Corballis, Georgia Tech University; Clayton Curtis, New York University; Anders Dale, Massachusetts General Hospital; Antonio Damasio, University of Southern California; Hanna Damasio, University of Southern California; Lila Davachi, New York University; Daniel C. Dennett, Tufts University; Michel Desmurget, Centre de Neuroscience Cognitive; Mark D’Esposito, University of California, Berkeley; Joern Diedrichsen, University College London; Nina Dronkers, University of California, Davis; Paul Eling, Radboud University Nijmegen; Russell Epstein, University of Pennsylvania; Martha Farah, University of Pennsylvania; Harlen Fichtenholtz, Duke University; Peter T. Fox, University of Texas; Karl Friston, Institute of Neurology, London; Rusty Gage, Salk Institute; Jack Gallant, University of California, Berkeley; Vittorio Gallese, University of Parma, Italy; Isabel xv

xvi | Acknowledgments

Gauthier, Vanderbilt University; Priyanka Ghosh; Christian Gerlach, University of Southern Denmark; Robbin Gibb, University of Lethbridge; Mitchell Glickstein, University College London and Dartmouth College; Gail Goodman, University of California, Davis; Elizabeth Gould, Princeton University; Jay E. Gould, University of West Florida; Scott Grafton, University of California, Santa Barbara; Charlie Gross, Princeton University; Nouchine Hadjikhani, Massachusetts General Hospital; Peter Hagoort, Max Planck Institute for Psycholinguistics; Todd Handy, University of British Columbia; Eliot Hazeltine, University of Iowa; Hans-Jochen Heinze, University of Madgeberg; Arturo Hernandez, University of Houston; Laura Hieber, University of California, Berkeley; Steven A. Hillyard, University of California, San Diego; Hermann Hinrichs, University of Madgeberg; Jens-Max Hopf, University of Magdeburg; Joseph Hopfinger, University of California, Davis; Richard Howard, National University of Singapore; Drew Hudson, University of California, Berkeley; Akira Ishiguchi, Ochanomizu University; Lucy Jacobs, University of California, Berkeley; Amishi Jha, University of California, Davis; Cindy Jordan, Michigan State University; Tim Justus, VA Medical Center, Martinez, California; Nancy Kanwisher, Massachusetts Institute of Technology; Larry Katz, Duke University; Steven Keele, University of Oregon; Leon Kenemans, University of Utrecht; Steve Kennerley, University of California, Berkeley; Alan Kingstone, University of British Columbia; Robert T. Knight, University of California, Berkeley; Talia Konkle, Harvard University; Stephen M. Kosslyn, Harvard University; Neal Kroll, University of California, Davis; Leah Krubitzer, University of California, Davis; Marta Kutas, University of California, San Diego; Ayelet Landau, University of California, Berkeley; Joseph E. Le Doux, New York University; Matt Lieberman, University of California, Los Angeles; Steven J. Luck, University of California, Davis; Jennifer Mangels, Graduate Center at the City University of New York; Chad Marsolek, University of Minnesota; Nancy Martin, University of California, Davis; James L. McClelland, Stanford University; George A. Miller, Princeton University; Teresa Mitchell, Duke University; Ryan Morehead, University of California, Berkeley; Amy Needham, Duke University; Kevin Ochsner, Columbia University; Ken A. Paller, Northwestern University; Jasmeet K. Pannu, University of Arizona;

Galina V. Paramei, Liverpool Hope University; Steven E. Petersen, Washington University School of Medicine; Steven Pinker, Harvard University; Lara Polse, University of California, San Diego; Michael I. Posner, University of Oregon; David Presti, University of California, Berkeley; Robert Rafal, University of Bangor; Marcus Raichle, Washington University School of Medicine; Charan Ranganath, University of California, Davis; Patricia Reuter-Lorenz, University of Michigan; Jesse Rissman, University of California, Los Angeles; Matthew Rushworth, University of Oxford; Alexander Sack, Maastricht University; Mikko E. Sams, University of Tampere; Donatella Scabini, University of California, Berkeley; Daniel Schacter, Harvard University; Ariel Schoenfeld, University of Magdeburg; Michael Scholz, University of Magdeberg; Art Shimamura, University of California, Berkeley; Michael Silver, University of California, Berkeley; Michael Silverman, Oregon Health Sciences University; Noam Sobel, Weizmann Institute of Science; Allen W. Song, Duke University; Larry Squire, University of California, San Diego; Alit Stark-Inbar, University of California, Berkeley; Michael Starks, 3DTV Corporation; Thomas M. Talavage, Massachusetts General Hospital; Keiji Tanaka, Riken Institute; Michael Tarr, Brown University; Ed Taylor; Jordan Taylor, Princeton University; Sharon L. Thompson-Schill, University of Pennsylvania; Roger Tootell, Massachusetts General Hospital; Anne M. Treisman, Princeton University; Carrie Trutt, Duke University; Endel Tulving, Rotman Research Institute, Baycrest Center; John Vollrath; John Wallis; C. Mark Wessinger, University of Nevada, Reno; Susanne Wiking, University of Tromsø; Kevin Wilson, Gettysburg College; Ginger Withers, Oregon Health Sciences University; Marty G. Woldorff, Duke University; Andrew Yonelinas, University of California, Davis. Often we forget to thank the many people, some of whom have generously given hundreds of hours of their time, for being participants in the research work that we discuss; without their contributions, cognitive neuroscience would not be where it is today. Finally, we would like to thank the outstanding editorial and production team at W. W. Norton, Michael Zierler, Diane Cipollone, Aaron Javsicas, Sheri Snavely, Callinda Taylor, Shira Averbuch, and Eric Pier-Hocking, whose sharp eyes and wise counsel have helped us produce this exciting new edition of our textbook.

F O U RT H E D I T I O N

Cognitive Neuroscience The Biology of the Mind

In science it often happens that scientists say, “You know that’s a really good argument; my position is mistaken,” and then they actually change their minds and you never hear that old view from them again. They really do it. It doesn’t happen as often as it should, because scientists are human and change is sometimes painful. But it happens every day. I cannot recall the last time something like that happened in politics or religion. ~Carl Sagan, 1987

A Brief History of Cognitive Neuroscience

1

chapter

AS ANNE GREEN WALKED to the gallows in the castle yard of Oxford, England, in 1650, she must have been feeling scared, angry, and frustrated. She was about to be executed for a crime she had not committed: murdering her stillborn child. Many thoughts raced through her head, but “I am about to play a role in the founding of clinical neurology and neuroanatomy” although accurate, OUTLINE certainly was not one of them. She proclaimed her innocence to the crowd, A Historical Perspective a psalm was read, and she was hanged. She hung there for a full half hour before she was taken down, pronounced dead, and placed in a coffin provided The Brain Story by Drs. Thomas Willis and William Petty. This was when Anne Green’s luck The Psychological Story began to improve. Willis and Petty were physicians and had permission from King Charles I to dissect, for medical research, the bodies of any criminals The Instruments of Neuroscience killed within 21 miles of Oxford. So, instead of being buried, Anne’s body was The Book in Your Hands carried to their office. An autopsy, however, was not what took place. As if in a scene from Edgar Allan Poe, the coffin began to emit a grumbling sound. Anne was alive! The doctors poured spirits in her mouth and rubbed a feather on her neck to make her cough. They rubbed her hands and feet for several minutes, bled five ounces of her blood, swabbed her neck wounds with turpentine, and cared for her through the night. The next morning, able to drink fluids and feeling more chipper, Anne asked for a beer. Five days later, she was out of bed and eating normally (Molnar, 2004; Zimmer, 2004). After her ordeal, the authorities wanted to hang Anne again. But Willis and Petty fought in her defense, arguing that her baby had been stillborn and its death was not her fault. They declared that divine providence had stepped in and provided her miraculous escape from death, thus proving her innocence. Their arguments prevailed. Anne was set free and went on to marry and have three more children. This miraculous experience was well publicized in England (Figure 1.1). Thomas Willis (Figure 1.2) owed much to Anne Green and the fame brought to him by the events of her resurrection. With it came money he desperately needed and the prestige to publish his work and disseminate his ideas, and he had some good ones. An inquisitive neurologist, he actually coined the term neurology and became one of the best-known doctors of his time. He was the first anatomist to link abnormal human behaviors to changes in brain structure. He drew these conclusions after treating patients throughout their

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FIGURE 1.1 An artistic rendition of the miraculous resurrection of Anne Green in 1650.

lives and autopsying them after their deaths. Willis was among the first to link specific brain damage to specific behavioral deficits, and to theorize how the brain transfers information in what would later be called neuronal conduction. With his colleague and friend Christopher Wren (the architect who designed St. Paul’s Cathedral in London), Willis created drawings of the human brain that remained the most accurate representations for 200 years (Figure 1.3). He also coined names for a myriad of brain regions (Table 1.1; Molnar, 2004; Zimmer, 2004). In short, Willis set in motion the ideas and knowledge base that took hundreds of years to develop into what we know today as the field of cognitive neuroscience. In this chapter, we discuss some of the scientists and physicians who have made important contributions to this field. You will discover the origins of cognitive neuroscience and how it has developed into what it is today: a discipline geared toward understanding how the brain works, how brain structure and function affect behavior, and ultimately how the brain enables the mind.

arises from awareness, perception, and reasoning), and neuroscience (the study of how the nervous system is organized and functions). This seemed the perfect term to describe the question of understanding how the functions of the physical brain can yield the thoughts and ideas of an intangible mind. And so the term took hold in the scien- FIGURE 1.2 Thomas Willis (1621–1675), a founder of tific community. clinical neuroscience. When considering the miraculous properties of brain function, bear in mind that Mother Nature built our brains through the process of evolution; they were not designed by a team of rational engineers. While life first appeared on our 4.5-billion-year-old Earth approximately 3.8 billion years ago, human brains, in their present form, have been around for only about 100,000 years, a mere drop in the bucket. The primate brain appeared between 34 million and 23 million years ago, during the Oligocene epoch. It evolved into the progressively larger brains of the great apes in the Miocene epoch between roughly 23 million and 7 million years ago. The human

A Historical Perspective The scientific field of cognitive neuroscience received its name in the late 1970s in the back seat of a New York City taxi. One of us (M.S.G.) was riding with the great cognitive psychologist George A. Miller on the way to a dinner meeting at the Algonquin Hotel. The dinner was being held for scientists from Rockefeller and Cornell universities, who were joining forces to study how the brain enables the mind—a subject in need of a name. Out of that taxi ride came the term cognitive neuroscience— from cognition, or the process of knowing (i.e., what

FIGURE 1.3 The human brain (ventral view) drawn by Christopher Wren for Thomas Willis, published in Willis’s The Anatomy of the Brain and Nerves.

The Brain Story | 5 TABLE 1.1

A Selection of Terms Coined by Thomas Willis

Term

Definition

Anterior commissure

Axonal fibers connecting the middle and inferior temporal gyri of the left and right hemispheres.

Cerebellar peduncles

Axonal fibers connecting the cerebellum and brainstem.

Claustrum

A thin sheath of gray matter located between two brain areas: the external capsule and the putamen.

Corpus striatum

A part of the basal ganglia consisting of the caudate nucleus and the lenticular nucleus.

Inferior olives

The part of the brainstem that modulates cerebellar processing.

Internal capsule

White matter pathways conveying information from the thalamus to the cortex.

Medullary pyramids

A part of the medulla that consists of corticospinal fibers.

Neurology

The study of the nervous system and its disorders.

Optic thalamus

The portion of the thalamus relating to visual processing.

Spinal accessory nerve

The 11th cranial nerve, which innervates the head and shoulders.

Stria terminalis

The white matter pathway that sends information from the amygdala to the basal forebrain.

Striatum

Gray matter structure of the basal ganglia.

Vagus nerve

The 10th cranial nerve, which, among other functions, has visceral motor control of the heart.

lineage diverged from the last common ancestor that we shared with the chimpanzee somewhere in the range of 5–7 million years ago. Since that divergence, our brains have evolved into the present human brain, capable of all sorts of wondrous feats. Throughout this book, we will be reminding you to take the evolutionary perspective: Why might this behavior have evolved? How could it promote survival and reproduction? WWHGD? (What would a hunter-gather do?) The evolutionary perspective often helps us to ask more informed questions and provides insight into how and why the brain functions as it does. During most of our history, humans were too busy to think about thought. Although there can be little doubt that the brains of our long-ago ancestors could engage in such activities, life was given over to more practical matters, such as surviving in tough environments, developing ways

to live better by inventing agriculture or domesticating animals, and so forth. Nonetheless, the brain mechanisms that enable us to generate theories about the characteristics of human nature thrived inside the heads of ancient humans. As civilization developed to the point where dayto-day survival did not occupy every hour of every day, our ancestors began to spend time looking for causation and constructing complex theories about the motives of fellow humans. Examples of attempts to understand the world and our place in it include Oedipus Rex (the ancient Greek play that deals with the nature of the child–parent conflict) and Mesopotamian and Egyptian theories on the nature of religion and the universe. Although the pre-Socratic Greek philosopher, Thales, rejected supernatural explanations of phenomena and proclaimed that every event had a natural cause (presaging modern cognitive neuroscience), the early Greeks had one big limitation: They did not have the methodology to explore the mind systematically through experimentation. It wasn’t until the 19th century that the modern tradition of observing, manipulating, and measuring became the norm, and scientists started to determine how the brain gets its jobs done. To understand how biological systems work, a laboratory is needed and experiments have to be performed to answer the questions under study and to support or refute the hypotheses and conclusions that have been made. This approach is known as the scientific method, and it is the only way that a topic can move along on sure footing. And in the case of cognitive neuroscience, there is no end to the rich phenomena to study.

The Brain Story Imagine that you are given a problem to solve. A hunk of biological tissue is known to think, remember, attend, solve problems, tell jokes, want sex, join clubs, write novels, exhibit bias, feel guilty, and do a zillion other things. You are supposed to figure out how it works. You might start by looking at the big picture and asking yourself a couple of questions. “Hmmm, does the blob work as a unit with each part contributing to a whole? Or, is the blob full of individual processing parts, each carrying out specific functions, so the result is something that looks like it is acting as a whole unit?” From a distance the city of New York (another type of blob) appears as an integrated whole, but it is actually composed of millions of individual processors—that is, people. Perhaps people, in turn, are made of smaller, more specialized units. This central issue—whether the mind is enabled by the whole brain working in concert or by specialized parts of the brain working at least partly independently—is what fuels much of modern research in cognitive neuroscience.

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As we will see, the dominant view has changed back and forth over the years, and it continues to change today. Thomas Willis foreshadowed cognitive neuroscience with the notion that isolated brain damage (biology) could affect behavior (psychology), but his insights slipped from view. It took another century for Willis’s ideas to resurface. FIGURE 1.4 Franz Joseph They were expanded upon by Gall (1758–1828), one of the a young Austrian physician founders of phrenology. and neuroanatomist, Franz Joseph Gall (Figure 1.4). After studying numerous patients, Gall became convinced that the brain was the organ of the mind and that innate faculties were localized in specific regions of the cerebral cortex. He thought that the brain was organized around some 35 or more specific functions, ranging from cognitive basics such as language and color perception to more ephemeral capacities such as affection and a moral sense, and each was supported by specific brain regions. These ideas were well received, and Gall took his theory on the road, lecturing throughout Europe. Building on his theories, Gall and his disciple Johann Spurzheim hypothesized that if a person used one of the faculties with greater frequency than the others, the part of the brain representing that function would grow (Gall & Spurzheim, 1810–1819). This increase in local brain

a

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size would cause a bump in the overlying skull. Logically, then, Gall and his colleagues believed that a careful analysis of the skull could go a long way in describing the personality of the person inside the skull. Gall called this technique anatomical personology (Figure 1.5). The idea that character could be divined through palpating the skull was dubbed phrenology by Spurzheim and, as you may well imagine, soon fell into the hands of charlatans. Some employers even required job applicants to have their skulls “read” before they were hired. Gall, apparently, was not politically astute. When asked to read the skull of Napoleon Bonaparte, Gall did not ascribe to his skull the noble characteristics that the future emperor was quite sure he possessed. When Gall later applied to the Academy of Science of Paris, Napoleon decided that phrenology needed closer scrutiny and ordered the Academy to obtain some scientific evidence of its validity. Although Gall was a physician and neuroanatomist, he was not a scientist. He observed correlations and sought only to confirm, not disprove, them. The Academy asked physiologist Marie-Jean-Pierre Flourens (Figure 1.6) to see if he could come up with any concrete findings that could back up this theory. Flourens set to work. He destroyed parts of the brains of pigeons and rabbits and observed what happened. He was the first to show that indeed certain parts of the brain were responsible for certain functions. For instance, when he removed the cerebral hemispheres, the animal no longer had perception, motor ability, and judgment.

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FIGURE 1.5 (a) An analysis of Presidents Washington, Jackson, Taylor, and McKinley by Jessie A. Fowler, from the Phrenological Journal, June 1898. (b) The phrenological map of personal characteristics on the skull, from the American Phrenological Journal, March 1848. (c) Fowler & Wells Co. publication on marriage compatibility in connection with phrenology, 1888.

The Brain Story | 7

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FIGURE 1.6 (a) Marie-Jean-Pierre Flourens (1794–1867), who supported the idea later termed the aggregate field theory. (b)The posture of a pigeon deprived of its cerebral hemispheres, as described by Flourens.

Without the cerebellum, the animals became uncoordinated and lost their equilibrium. He could not, however, find any areas for advanced abilities such as memory or cognition and concluded that these were more diffusely scattered throughout the brain. Flourens developed the notion that the whole brain participated in behavior, a view later known as the aggregate field theory. In 1824, Flourens wrote, “All sensations, all perceptions, and all volitions occupy the same seat in these (cerebral) organs. The faculty of sensation, percept and volition is then essentially one faculty.” The theory of localized brain functions, known as localizationism, fell out of favor. That state of affairs didn’t last for too long, however. New evidence obtained through clinical observations and autopsies started trickling in from across Europe, and it helped to swing the pendulum slowly back to the localizationist view. In 1836 a neurologist from Montpellier, Marc Dax, provided one of the first bits of evidence. He sent a report to the Academy of Sciences about three patients, noting that each had speech disturbances and similar left-hemisphere lesions found at autopsy. At the time, a report from the provinces got short shrift in Paris, and it would be another 30 years before anyone took much notice of this observation that speech could be disrupted by a lesion to one hemiFIGURE 1.7 John Hughlings sphere only. Jackson (1835–1911), an Meanwhile, in England, English neurologist who was the neurologist John Hughone of the first to recognize lings Jackson (Figure 1.7) the localizationist view.

began to publish his observations on the behavior of persons with brain damage. A key feature of Jackson’s writings was the incorporation of suggestions for experiments to test his observations. He noticed, for example, that during the start of their seizures, some epileptic patients moved in such characteristic ways that the seizure appeared to be stimulating a set map of the body in the brain; that is, the clonic and tonic jerks in muscles, produced by the abnormal epileptic firings of neurons in the brain, progressed in the same orderly pattern from one body part to another. This phenomenon led Jackson to propose a topographic organization in the cerebral cortex—that is, a map of the body was represented across a particular cortical area, where one part would represent the foot, another the lower leg, and so on. As we will see, this proposal was verified over a half century later by Wilfred Penfield. Jackson was one of the first to realize this essential feature of brain organization. Although Jackson was also the first to observe that lesions on the right side of the brain affect visuospatial processes more than do lesions on the left side, he did not maintain that specific parts of the right side of the brain were solely committed to this important human cognitive function. Being an observant clinical neurologist, Jackson noticed that it was rare for a patient to lose a function completely. For example, most people who lost their capacity to speak following a cerebral stroke could still say some words. Patients unable to direct their hands voluntarily to specific places on their bodies could still easily scratch those places if they itched. When Jackson made these observations, he concluded that many regions of the brain contributed to a given behavior. Meanwhile, the well-known and respected Parisian physician Paul Broca (Figure 1.8a) published, in 1861, the results of his autopsy on a patient who had been nicknamed Tan—perhaps the most famous neurological case in history. Tan had developed aphasia: He could understand language, but “tan” was the only word he could utter. Broca found that Tan (his real name was Leborgne) had a syphilitic lesion in his left hemisphere in the inferior frontal lobe. This region of the brain has come to be called Broca’s area. The impact of this finding was huge. Here was a specific aspect of language that was impaired by a specific lesion. Soon Broca had a series of such patients. This theme was picked up by the German neurologist Carl Wernicke. In 1876, Wernicke reported on a stroke victim who (unlike Broca’s patient) could talk quite freely but made little sense when he spoke. Wernicke’s patient also could not understand spoken or written language. He had a lesion in a more posterior region of the left hemisphere, an area in and around where the temporal and parietal lobes meet, which is now referred to as Wernicke’s area (Figure 1.8b).

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Pc B A

b

a

FIGURE 1.8 (a) Paul Broca (1824–1880). (b) The connections between the speech centers, from Wernicke’s 1876 article on aphasia. A = Wernicke’s sensory speech center; B = Broca’s area for speech; Pc = Wernicke’s area concerned with language comprehension and meaning.

Today, differences in how the brain responds to focal disease are well known (H. Damasio et al., 2004; R. J. Wise, 2003), but a little over 100 years ago Broca’s and Wernicke’s discoveries were earth-shattering. (Note that people had largely forgotten Willis’s observations that isolated brain damage could affect behavior. Throughout the history of brain science, an unfortunate and oft repeated trend is that we fail to consider crucial observations made by our predecessors.) With the discoveries of Broca and Wernicke, attention was again paid to this startling point: Focal brain damage causes specific behavioral deficits. As is so often the case, the study of humans leads to questions for those who work on animal models. Shortly after Broca’s discovery, the German physiologists Gustav Fritsch and Eduard Hitzig electrically stimulated discrete parts of a dog brain and observed that this stimulation produced characteristic movements in the dog. This discovery led neuroanatomists to more closely analyze the cerebral cortex and its cellular organization; they wanted support for their ideas about the importance of local

regions. Because these regions performed different functions, it followed that they ought to look different at the cellular level. Following this logic, German neuroanatomists began to analyze the brain by using microscopic methods to view the cell types in different brain regions. Perhaps the most famous of the group was Korbinian Brodmann, who analyzed the cellular organization of the cortex and characterized 52 distinct regions (Figure 1.9). He published his cortical maps in 1909. Brodmann used tissue stains, such as the one developed by Franz Nissl, that permitted him to visualize the different cell types in different brain regions. How cells differ between brain regions is called cytoarchitectonics, or cellular architecture. Soon many now-famous anatomists, including Oskar Vogt, Vladimir Betz, Theodor Meynert, Constantin von

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FIGURE 1.9 Sampling of the 52 distinct areas described by Brodmann on the basis of cell structure and arrangement.

11 a

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FIGURE 1.10 (a) Camillo Golgi (1843–1926), cowinner of the Nobel Prize in 1906. (b) Golgi’s drawings of different types of ganglion cells in dog and cat.

The Brain Story | 9 Economo, Gerhardt von Bonin, and Percival Bailey, contributed to this work, and several subdivided the cortex even further than Brodmann had. To a large extent, these investigators discovered that various cytoarchitectonically described brain areas do indeed represent functionally distinct brain regions. For example, Brodmann first distinguished area 17 from area 18—a distinction that has proved correct in subsequent functional studies. The characterization of the primary visual area of the cortex, area 17, as distinct from surrounding area 18, remarkably demonstrates the power of the cytoarchitectonic approach, as we will consider more fully in Chapter 2. Despite all of this groundbreaking work in cytoarchitectonics, the truly huge revolution in our understanding of the nervous system was taking place elsewhere, in Italy and Spain. There, an intense struggle was going on between two brilliant neuroanatomists. Oddly, it was the work of one that led to the insights of the other. Camillo Golgi (Figure 1.10), an Italian physician, developed one of the most famous cell stains in the history of the world: the silver method for staining neurons—la reazione nera, “the black reaction,” that impregnated individual neurons with silver chromate. This stain permits visualization of individual neurons in their entirety. Using Golgi’s method, Santiago Ramón y Cajal (Figure 1.11) went on to find that, contrary to the view of Golgi and others, neurons were discrete entities. Golgi had believed that the whole brain was a syncytium, a continuous mass of tissue that shares a common cytoplasm. Ramón y Cajal, who some call the father of modern neuroscience, was the first to identify the unitary nature of neurons and to articulate what came to be known as the neuron doctrine, the concept that the nervous system is made up of individual cells. He also recognized that the transmission of electrical information

Dire

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elec

trica

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nsm

issio

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Dendrites Cell body Axon

FIGURE 1.12 A bipolar retinal cell, illustrating the dendrites and axon of the neuron.

went in only one direction, from the dendrites down to the axonal tip (Figure 1.12). Many gifted scientists were involved in the early history of the neuron doctrine (Shepherd, 1991). For example, Jan Evangelista Purkinje (Figure 1.13), a Czech, not only described the first nerve cell in the nervous system in 1837 but also invented the stroboscope, described common visual phenomena, and made

a

Dendrites Cell body

Axon a

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FIGURE 1.11 (a) Santiago Ramón y Cajal (1852–1934), cowinner of the Nobel Prize in 1906. (b) Ramón y Cajal’s drawing of the afferent inflow to the mammalian cortex.

b FIGURE 1.13 (a) Jan Evangelista Purkinje (1787–1869), who described the first nerve cell in the nervous system. (b) A Purkinje cell of the cerebellum.

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A Brief History of Cognitive Neuroscience

b

FIGURE 1.14 (a) Hermann Ludwig von Helmholtz (1821–1894). (b) Helmholtz’s apparatus for measuring the velocity of nerve conduction.

a host of other major discoveries. Hermann von Helmholtz (Figure 1.14) figured out that electrical current in the cell was not a by-product of cellular activity, but the medium that was actually carrying information along the axon of a nerve cell. He was also the first to suggest that invertebrates would be good models for studying vertebrate brain mechanisms. British physiologist Sir Charles Sherrington vigorously pursued the neuron’s behavior as a unit and, indeed, coined the term synapse to describe the junction between two neurons. With Golgi, Ramón y Cajal, and these other bright minds, the neuron doctrine was born—a discovery whose importance was highlighted by the 1906 Nobel Prize in Physiology or Medicine shared by Golgi and Ramón y Cajal, and later by the 1932 Nobel Prize awarded to Sherrington. As the 20th century progressed, the localizationist views were mediated by those who saw that, even though particular neuronal locations might serve independent functions, the network of these locations and the interaction between them are what yield the integrated, holistic behavior that humans exhibit. Once again this neglected idea had previously been discussed nearly a century earlier by the French biologist Claude Bernard, who wrote in 1865: If it is possible to dissect all the parts of the body, to isolate them in order to study them in their structure, form and connections it is not the same in life, where all parts cooperate at the same time in a common aim. An organ does not live on its own, one could often say it did not exist anatomically, as the boundary established is sometimes purely arbitrary. What lives, what exists, is the whole, and if one studies all the parts of any mechanisms separately, one does not know the way they work.

Thus, scientists have come to believe that the knowledge of the parts (the neurons and brain structures) must be understood in conjunction with the whole (i.e., what the parts make when they come together: the mind). Next we explore the history of research on the mind.

The Psychological Story Physicians were the early pioneers studying how the brain worked. In 1869 a Dutch ophthalmologist, Franciscus Donders, was the first to propose the now-common method of using differences in reaction times to infer differences in cognitive processing. He suggested that the difference in the amount of time it took to react to a light and the amount of time needed to react to a particular color of light was the amount of time required for the process of identifying a color. Psychologists began to use this approach, claiming that they could study the mind by measuring behavior, and experimental psychology was born. Before the start of experimental psychological science the mind had been the province of philosophers, who wondered about the nature of knowledge and how we come to know things. The philosophers had two main positions: rationalism and empiricism. Rationalism grew out of the Enlightenment period and held that all knowledge could be gained through the use of reason alone: Truth was intellectual, not sensory. Through thinking, then, rationalists would determine true beliefs and would reject beliefs that, although perhaps comforting, were unsupportable and even superstitious. Among intellectuals and scientists, rationalism replaced religion and became the only way to think about the world. In particular, this view, in one form or another,

The Psychological Story | 11

MILESTONES IN COGNITIVE NEUROSCIENCE

Interlude In textbook writing, authors use broad strokes to communicate milestones that have become important to people’s thinking over a long period of time. It would be folly, however, not to alert the reader that these scientific advances took place in a complex and intriguing cultural, intellectual, and personal setting. The social problems that besieged the world’s first scientists remain today, in full glory: Issues of authorship, ego, funding, and credit are all integral to the fabric of intellectual life. Much as teenagers never imagine that their parents once had the same interests, problems, and desires as they do, novitiates in science believe they are tackling new issues for the first time in human history. Gordon Shepherd (1991), in his riveting account Foundations of the Neuron Doctrine, detailed the variety of forces at work on the figures we now feature in our brief history. Shepherd noted how the explosion of research on the nervous system started in the 18th century as part of the intense activity swirling around the birth of modern science. As examples, Robert Fulton invented the steam

a

engine in 1807, and Hans Christian Ørsted discovered electromagnetism. Of more interest to our concerns, Leopoldo Nobili, an Italian physicist, invented a precursor to the galvanometer—a device that laid the foundation for studying electrical currents in living tissue. Many years before, in 1674, Anton van Leeuwenhoek in Holland had used a primitive microscope to view animal tissue (Figure1). One of his first observations was of a cross section of a cow’s nerve in which he noted “very minute vessels.” This observation was consistent with René Descartes’s idea that nerves contained fluid or “spirits,” and these spirits were responsible for the flow of sensory and motor information in the body (Figure 2). To go further, however, this revolutionary work would have to overcome the technical problems with early microscopes, not the least of which was the quality of glass used in the lens. Chromatic aberrations made them useless at higher magnification. It was not until lens makers solved this problem that microscopic anatomy again took center stage in the history of biology.

b

FIGURE 1 (a) Anton van Leeuwenhoek (1632–1723). (b) One of the original microscopes used by Leeuwenhoek, composed of two brass plates holding the lens.

FIGURE 2 René Descartes (1596–1650). Portrait by Frans Hals.

was supported by René Descartes, Baruch Spinoza, and Gottfried Leibniz. Although rationalism is frequently equated with logical thinking, the two are not identical. Rationalism considers such issues as the meaning of life, whereas logic does not. Logic simply relies on inductive reasoning, statistics, probabilities, and the like. It does not concern itself with personal mental states like happiness, self-interest, and public good. Each person weighs these

issues differently, and as a consequence, a rational decision is more problematic than a simple logical decision. Empiricism, on the other hand, is the idea that all knowledge comes from sensory experience, that the brain began life as a blank slate. Direct sensory experience produces simple ideas and concepts. When simple ideas interact and become associated with one another, complex ideas and concepts are created in an individual’s knowledge system. The British philosophers—from

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Thomas Hobbes in the 17th century, through John Locke and David Hume, to John Stuart Mill in the 19th century—all emphasized the role of experience. It is no surprise, then, that a major school of experimental psychology arose from this associationist view. Psychological associationists believed that the aggregate of a person’s experiFIGURE 1.15 Edward L. Thorndike (1874–1949). ence determined the course of mental development. One of the first scientists to study associationism was Hermann Ebbinghaus, who, in the late 1800s, decided that complex processes like memory could be measured and analyzed. He took his lead from the great psychophysicists Gustav Fechner and Ernst Heinrich Weber, who were hard at work relating the physical properties of things such as light and sound to the psychological experiences that they produce in the observer. These measurements were rigorous and reproducible. Ebbinghaus was one of the first to understand that mental processes that are more internal, such as memory, also could be measured (see Chapter 9). Even more influential to the shaping of the associationist view was the classic 1911 monograph Animal Intelligence: An Experimental Study of the Associative Processes in Animals, by Edward Thorndike (Figure 1.15). In this volume, Thorndike articulated his law of effect, which was the first general statement about the nature of associations. Thorndike simply observed that a response that was

a

followed by a reward would be stamped into the organism as a habitual response. If no reward followed a response, the response would disappear. Thus, rewards provided a mechanism for establishing a more adaptive response. Associationism came to be dominated by American behavioral psychologist John B. Watson (Figure 1.16), who proposed that psychology could be objective only if it were based on observable behavior. He rejected Ebbinghaus’s methods and declared that all talk of mental processes, which cannot be publicly observed, should be avoided. Associationism became committed to an idea widely popularized by Watson that he could turn any baby into anything. Learning was the key, he proclaimed, and everybody had the same neural equipment on which learning could build. Appealing to the American sense of equality, American psychology was giddy with this idea of the brain as a blank slate upon which to build through learning and experience, and every prominent psychology department in the country was run by people who held this view. Behaviorist–associationist psychology went on despite the already well-established position—first articulated by Descartes, Leibniz, Kant, and others—that complexity is built into the human organism. Sensory information is merely data on which preexisting mental structures act. This idea, which dominates psychology today, was blithely asserted in that golden age, and later forgotten or ignored. Although American psychologists were focused on behaviorism, the psychologists in Britain and Canada were not. Montreal became a hot spot for new ideas on how biology shapes cognition and behavior. In 1928, Wilder Penfield (Figure 1.17), an American who had studied neuropathology with Sir Charles Sherrington at Oxford,

b

FIGURE 1.16 (a) John B. Watson (1878–1958). (b) Watson and “Little Albert” during one of Watson’s fear-conditioning experiments.

The Psychological Story | 13

FIGURE 1.19 Brenda Milner (1918–). FIGURE 1.17 Wilder Penfield (1891–1976).

FIGURE 1.18 Donald O. Hebb (1904–1985).

became that city’s first neurosurgeon. In collaboration with Herbert Jasper, he invented the Montreal procedure for treating epilepsy, in which he surgically destroyed the neurons in the brain that produced the seizures. To determine which cells to destroy, Penfield stimulated various parts of the brain with electrical probes and observed the results on the patients—who were awake, lying on the operating table under local anesthesia only. From these observations, he was able to create maps of the sensory and motor cortices in the brain (Penfield & Jasper, 1954) that Hughlings Jackson had predicted over half a century earlier. Soon he was joined by a Nova Scotian psychologist, Donald Hebb (Figure 1.18), who spent time working with Penfield studying the effects of brain surgery and injury on the functioning of the brain. Hebb became convinced that the workings of the brain explained behavior and that the psychology and biology of an organism could not be separated. Although this idea—which kept popping up only to be swept under the carpet again and again over the past few hundred years—is well accepted now, Hebb was a maverick at the time. In 1949 he published a book, The Organization of Behavior: A Neuropsychological Theory (Hebb, 1949), that rocked the psychological world. In it he postulated that learning had a biological basis. The well-known neuroscience mantra “cells that fire together, wire together” is a distillation of his proposal that neurons can combine together into a single processing unit and the connection patterns of these units make up the ever-changing algorithms determining the brain’s response to a stimulus. He pointed out that the brain is active all the time, not just when stimulated by an impulse, and that inputs from the outside can only modify the ongoing activity. Hebb’s theory was subsequently used in the design of artificial neural networks. Hebb’s British graduate student, Brenda Milner (Figure 1.19), continued the behavioral studies on Penfield’s patients, both before and after their surgery.

FIGURE 1.20 George A. Miller (1920–2012).

When patients began to complain about mild memory loss after surgery, she became interested in memory and was the first to provide anatomical and physiological proof that there are multiple memory systems. Brenda Milner, 60 years later, is still associated with the Montreal Neurological Institute and has seen a world of change sweep across the study of brain, mind, and behavior. She was in the vanguard of cognitive neuroscience as well as one of the first in a long line of influential women in the field. The true end of the dominance of behaviorism and stimulus–response psychology in America did not come until the late 1950s. Psychologists began to think in terms of cognition, not just behavior. George Miller (Figure 1.20), who had been a confirmed behaviorist, had a change of heart in the 1950s. In 1951, Miller wrote an influential book entitled Language and Communication and noted in the preface, “The bias is behavioristic.” Eleven years later he wrote another book, called Psychology, the Science of Mental Life—a title that signals a complete rejection of the idea that psychology should study only behavior. Upon reflection, Miller determined that the exact date of his rejection of behaviorism and his cognitive awakening was September 11, 1956, during the second Symposium on Information Theory, held at the Massachusetts Institute of Technology (MIT). That year had been a rich one for several disciplines. In computer science, Allen Newell and Herbert Simon successfully introduced Information Processing Language I, a powerful program that simulated the proof of logic theorems. The computer guru John von Neumann wrote the Silliman lectures on neural organization, in which he considered the possibility that the brain’s computational activities were similar to a massively parallel computer. A famous meeting on artificial intelligence was held at Dartmouth College, where Marvin Minsky, Claude Shannon (known as the father of information theory), and many others were in attendance.

14 | CHAPTER 1

A Brief History of Cognitive Neuroscience

FIGURE 1.21 Noam Chomsky (1928–).

FIGURE 1.22 Patricia Goldman-Rakic (1937–2003).

Big things were also happening in psychology. Signal detection and computer techniques, developed in World War II to help the U.S. Department of Defense detect submarines, were now being applied by psychologists James Tanner and John Swets to study perception. In 1956, Miller wrote his classic and entertaining paper, “The Magical Number Seven, Plus-or-Minus Two,” in which he showed that there is a limit to the amount of information that can be apprehended in a brief period of time. Attempting to reckon this amount of information led Miller to Noam Chomsky’s work (Figure 1.21; for a review see Chomsky, 2006), where he came across, perhaps, the most important development to the field. Chomsky showed him how the sequential predictability of speech follows from adherence to grammatical, not probabilistic, rules. A preliminary version of Chomsky’s ideas on syntactic theories, published in September 1956 in an article titled, “Three Models for the Description of Language, ” transformed the study of language virtually overnight. The deep message that Miller gleaned was that learning theory—that is, associationism, then heavily championed by B. F. Skinner—could in no way explain how language was learned. The complexity of language was built into the brain, and it ran on rules and principles that transcended all people and all languages. It was innate and it was universal. Thus, on September 11, 1956, after a year of great development and theory shifting, Miller realized that, although behaviorism had important theories to offer, it could not explain all learning. He then set out to understand the psychological implications of Chomsky’s theories by using psychological testing methods. His ultimate goal was to understand how the brain works as an integrated whole—to understand the workings of the brain and the mind. Many followed his new mission, and a few years later a new field was born: cognitive neuroscience. What has come to be a hallmark of cognitive neuroscience is that it is made up of an insalata mista (“mixed salad”) of different disciplines. Miller had stuck his

nose into the worlds of linguistics and computer science and come out with revelations for psychology and neuroscience. In the same vein, in the 1970s Patricia Goldman-Rakic (Figure 1.22) put together a multidisciplinary team of people working in biochemistry, anatomy, electrophysiology, pharmacology, and behavior. She was curious about one of Milner’s memory systems, working memory, and chose to ignore the behaviorists’ claim that the prefrontal cortex’s higher cognitive function could not be studied. As a result, she produced the first description of the circuitry of the prefrontal cortex and how it relates to working memory (Goldman-Rakic, 1987). Later she discovered that individual cells in the prefrontal cortex are dedicated to specific memory tasks, such as remembering a face or a voice. She also performed the first studies on the influence of dopamine on the prefrontal cortex. Her findings caused a phase shift in the understanding of many mental illnesses—including schizophrenia, which previously had been thought to be the result of bad parenting.

The Instruments of Neuroscience Changes in electrical impulses, fluctuations in blood flow, and shifts in utilization of oxygen and glucose are the driving forces of the brain’s business. They are also the parameters that are measured and analyzed in the various methods used to study how mental activities are supported by brain functions. The advances in technology and the invention of these methods have provided cognitive neuroscientists the tools to study how the brain enables the mind. Without these instruments, the discoveries made in the past 40 years would not have been possible. In this section, we provide a brief history of the people, ideas, and inventions behind some of the noninvasive techniques used in cognitive neuroscience. Many of these methods and their current applications are discussed in greater detail in Chapter 3.

The Electroencephalograph In 1875, shortly after Hermann von Helmholtz figured out that it was actually an electrical impulse wave that carried messages along the axon of a nerve, British scientist Richard Canton used a galvanometer to measure continuous spontaneous electrical activity from the cerebral cortex and skull surface of live dogs and apes. A fancier version, the “string galvanometer,” designed by a Dutch physician, Willem Einthoven, was able to make photographic recordings of the electrical activity. Using this

The Instruments of Neuroscience | 15 apparatus, the German psychiatrist Hans Berger published a paper describing recordings of a human brain’s electrical currents in 1929. He named the recording an electroencephalogram. Electroencephalography remained the sole technique for noninvasive brain study for a number of years.

Measuring Blood Flow in theBrain Angelo Mosso, a 19th-century Italian physiologist, was interested in blood flow in the brain and studied patients who had skull defects as the result of neurosurgery. During these studies, he recorded pulsations as blood flowed around and through their cortex (Figure 1.23) and noticed that the pulsations of the brain increased locally during mental activities such as mathematical calculations. He inferred that blood flow followed function. These observations, however, slipped from view and were not pursued until a few decades later when in 1928 John Fulton presented the case of patient Walter K., who was evaluated for a vascular malformation that resided above his visual cortex (Figure 1.24). The patient men-

FIGURE 1.24 Walter K.’s head with a view of the skull defect over the occipital cortex.

FIGURE 1.25 Seymour S. Kety (1915–2000).

tioned that at the back of his head he heard a noise that increased when he used his eyes, but not his other senses. This noise was a bruit, the sound that blood makes when it rushes through a narrowing of its channel. Fulton concluded that blood flow to the visual cortex varied with the attention paid to surrounding objects. Another 20 years slipped by, and Seymour Kety (Figure 1.25), a young physician at the University of Pennsylvania, realized that if you could perfuse arterial blood with an inert gas, such as nitrous oxide, then the gas would circulate through the brain and be absorbed independently of the brain’s metabolic activity. Its accumulation would be dependent only on physical parameters that could be measured, such as diffusion, solubility, and perfusion. With this idea in mind, he developed a method to measure the blood flow and metabolism of the human brain as a whole. Using more drastic methods in animals (they were decapitated; their brains were then removed and analyzed), Kety was able to measure the blood flow to specific regions of the brain (Landau et al., 1955). His animal studies provided evidence that blood flow was related directly to brain function. Kety’s method and results were used in developing positron emission tomography (described later in this section), which uses radiotracers rather than an inert gas.

Computerized Axial Tomography

FIGURE 1.23 Angelo Mosso’s experimental setup was used to measure the pulsations of the brain at the site of a skull defect.

Although blood flow was of interest to those studying brain function, having good anatomical images in order to locate tumors was motivating other developments in instrumentation. Investigators needed to be able to obtain three-dimensional views of the inside of the human body. In the 1930s, Alessandro Vallebona developed tomographic radiography, a technique in which a series of transverse sections are taken. Improving upon these

16 | CHAPTER 1

A Brief History of Cognitive Neuroscience

FIGURE 1.27 Michel M. Ter-Pogossian (1925–1996).

FIGURE 1.26 Irene Joliot-Curie (1897–1956).

initial attempts, UCLA neurologist William Oldendorf (1961) wrote an article outlining the first description of the basic concept later used in computerized tomography (CT), in which a series of transverse X-rays could be reconstructed into a three-dimensional picture. His concept was revolutionary, but he could not find any manufacturers willing to capitalize on his idea. It took insight and cash, which was provided by four lads from Liverpool, the company EMI, and Godfrey Newbold Hounsfield, a computer engineer who worked at the Central Research Laboratories of EMI, Ltd. EMI was an electronics firm that also owned Capitol Records and the Beatles’ recording contract. Hounsfield, using mathematical techniques and multiple two-dimensional X-rays to reconstruct a three-dimensional image, developed his first scanner, and as the story goes, EMI, flush with cash from the Beatles’ success, footed the bill. Hounsfield performed the first computerized axial tomography (CAT) scan in 1972.

Positron Emission Tomography and Radioactive Tracers While CAT was great for revealing anatomical detail, it revealed little about function. Researchers at Washington University, however, used CAT as the basis for developing positron emission tomography (PET), a noninvasive sectioning technique that could provide information about function. Observations and research by a huge number of people over many years have been incorporated into what ultimately is today’s PET. Its development is interwoven with that of the radioactive isotopes, aka “tracers,” that it employs. We previously noted the work of Seymour Kety done in the 1940s and 1950s. A few years earlier, in 1934, Irene Joliot-Curie (Figure 1.26) and Frederic Joliot-Curie discovered that some originally nonradioactive nuclides emitted penetrating radiation after being irradiated. This observation led Ernest O. Lawrence (the inventor of the

cyclotron) and his colleagues at the University of California, Berkeley to realize that the cyclotron could be used to produce radioactive substances. If radioactive forms of oxygen, nitrogen, or carbon could be produced, then they could be injected into the blood circulation and would become incorporated into biologically active molecules. These molecules would concentrate in an organ, FIGURE 1.28 Michael E. where the radioactivity would Phelps (1939–). begin to decay. The concentration of the tracers could then be measured over time, allowing inferences about metabolism to be made. In 1950, Gordon Brownell at Harvard University realized that positron decay (of a radioactive tracer) was associated with two gamma particles being emitted at 180 degrees. Using this handy discovery, a simple positron scanner with a pair of sodium iodide detectors was designed and built, and it was scanning patients for brain tumors in a matter of months (Sweet & Brownell, 1953). In 1959, David E. Kuhl, a radiology resident at the University of Pennsylvania, who had been dabbling with radiation since high school (did his parents know?), and Roy Edwards, an engineer, combined tomography with gamma-emitting radioisotopes and obtained the first emission tomographic image. The problem with most radioactive isotopes of nitrogen, oxygen, carbon, and fluorine is that their halflives are measured in minutes. Anyone who was going to use them had to have their own cyclotron and be ready to roll as the isotopes were created. It happened that Washington University had both a cyclotron that produced radioactive oxygen-15 (15O) and two researchers, Michel Ter-Pogossian and William Powers, who were interested in using it. They found that when injected into the bloodstream, 15O-labeled water could be used to measure blood flow in the brain (Ter-Pogossian & Powers, 1958). Ter-Pogossian (Figure 1.27) was joined in the 1970s by Michael Phelps (Figure 1.28), a graduate student who had started out his career as a Golden Gloves boxer. Excited about X-ray CT, they thought that they could adapt the technique to reconstruct the distribution within an organ of a short-lived “physiological” radionuclide from its emissions. They designed and constructed the first positron emission tomograph, dubbed PETT (positron emission transaxial tomography; Ter-Pogossian et al., 1975), which later was shortened to PET. Another metabolically important molecule in the brain is glucose. Under the direction of Joanna Fowler and Al

The Instruments of Neuroscience | 17 Wolf, using Brookhaven National Laboratory’s powerful cyclotron, 18F-labeled 2-fluorodeoxy-D-glucose (2FDG) was created (Ido et al., 1978). 18F has a half-life that is amenable for PET imaging and can give precise values of energy metabolism in the brain. The first work using PET to look for neural correlates of human behavior began when Phelps joined Kuhl at the University of Pennsylvania and together, using 2FDG, they established a method for imaging the tissue consumption of glucose. Phelps, in a leap of insight, invented the block detector, a device that eventually increased spatial resolution of PET from 3 centimeters to 3 millimeters.

Magnetic Resonance Imaging Magnetic resonance imaging (MRI) is based on the principle of nuclear magnetic resonance, which was first described and measured by Isidor Rabi in 1938. Discoveries made independently in 1946 by Felix Bloch at Harvard University and Edward Purcell at Stanford University expanded the understanding of nuclear magnetic resonance to liquids and solids. For example, the protons in a water molecule line up like little bar magnets when placed in a magnetic field. If the equilibrium of these protons is disturbed by zapping them with radio frequency pulses, then a measurable voltage is induced in a receiver coil. The voltage changes over time as a function of the proton’s environment. By analyzing the voltages, information about the examined tissue can be deduced. In 1971, while Paul Lauterbur (Figure 1.29) was on sabbatical, he was thinking grand thoughts as he ate a fast-food hamburger. He scribbled his ideas on a nearby napkin, and from these humble beginnings he developed the theoretical model that led to the invention of the first magnetic resonance imaging scanner, located at The State University of New York at Stony Brook (Lauterbur, 1973). (Lauterbur won the 2003 Nobel Prize in Physiology or Medicine, but his first attempt at publishing his findings was rejected by the journal Nature. He later quipped, “You could write the entire history of science in the last 50 years in terms of papers rejected by Science or Nature” [Wade, 2003]). It was another 20 years, however, before MRI was used to investigate brain function. This happened when researchers at Massachusetts General Hospital demonstrated that FIGURE 1.29 Paul Lauterbur following the injection of (1929–2007).

contrast material into the bloodstream, changes in the blood volume of a human brain, produced by physiological manipulation of blood flow, could be measured using MRI (Belliveau et al., 1990). Not only were excellent anatomical images produced, but they could be combined with physiology germane to brain function.

Functional Magnetic Resonance Imaging When PET was introduced, the conventional wisdom was that increased blood flow to differentially active parts of the brain was driven by the brain’s need for more oxygen. An increase in oxygen delivery permitted more glucose to be metabolized, and thus more energy would be available for performing the task. Although this idea sounded reasonable, little data were available to back it up. In fact, if this proposal were true, then increases in blood flow induced by functional demands should be equivalent to the increase in oxygen consumption. This would mean that the ratio of oxygenated to deoxygenated hemoglobin should stay constant. PET data, however, did not back this up (Raichle, 2008). Instead, Peter Fox and Marc Raichle, at Washington University, found that although functional activity induced increases in blood flow, there was no corresponding increase in oxygen consumption (Fox & Raichle, 1986). In addition, more glucose was being used than would be predicted from the amount of oxygen consumed (Fox et al., 1988). What was up with that? Raichle (2008) relates that oddly enough, a random scribble written in the margin of Michael Faraday’s lab notes in 1845 (Faraday, 1933) provided the hint that led to the solution of this puzzle. It was Linus Pauling and Charles Coryell who somehow happened upon this clue. Faraday had noted that dried blood was not magnetic and in the margin of his notes had written that he must try fluid blood. He was puzzled because hemoglobin contains iron. Ninety years later, Pauling and Coryell (1936), after reading Faraday’s notes, became curious too. They found that indeed oxygenated and deoxygenated hemoglobin behaved very differently in a magnetic field. Deoxygenated hemoglobin is weakly magnetic due to the exposed iron in the hemoglobin molecule. Years later, Kerith Thulborn (1982) remembered and capitalized on this property described by Pauling and Coryell, realizing that it was feasible to measure the state of oxygenation in vivo. Seiji Ogawa (1990) and his colleagues at AT&T Bell Laboratories tried manipulating oxygen levels by administering 100 % oxygen alternated with room air (21 % oxygen) to human subjects who were undergoing MRI. They discovered that on room air, the structure of the

18 | CHAPTER 1

A Brief History of Cognitive Neuroscience

Raichle understood the potential of these new scanning methods, but he also realized that some basic problems had to be solved. If generalized information about brain function and anatomy were to be obtained, then the scans from different individuals performing the same tasks under the same circumstances had to be comparable. This was proving difficult, however, since no two brains are precisely the same size and shape. Furthermore, early data was yielding a mishmash of results that varied in anatomical location from FIGURE 1.30 Images of a mouse brain under varying oxygen conditions. person to person. Eric Reiman, a psychiatrist working with Raichle, suggested that venous system was visible due to the contrast providaveraging blood flow across subjects might solve this ed by the deoxygenated hemoglobin that was present. problem. The results of this approach were clear and unOn 100 % O2, however, the venous system completely ambiguous (Fox, 1988). This landmark paper presented the first integrated approach for the design, execution, disappeared (Figure 1.30). Thus contrast depended on and interpretation of functional brain images. the blood oxygen level. BOLD (blood oxygen level– But what can be learned about the brain and the dependent) contrast was born. This technique led to behavior of a human when a person is lying prone in the development of functional magnetic resonance ima scanner? Cognitive psychologists Michael Posner, aging (fMRI). MRI does not use ionizing radiation, it Steve Petersen, and Gordon Shulman, at Washington combines beautifully detailed images of the body with University, developed innovative experimental paraphysiology related to brain function, and it is sensidigms, including the cognitive subtraction method (first tive (Figure 1.31). With all of these advantages, it did proposed by Donders), for use while PET scanning. The not take long for MRI and fMRI to be adopted by the methodology was soon applied to fMRI. This joining research community, resulting in explosive growth of together of cognitive psychology’s experimental methfunctional brain imaging. ods with brain imaging was the beginning of human Machines are useful, however, only if you know functional brain mapping. Throughout this book, we will what to do with them and what their limitations are. Air

O2

MRI Visual Cortex Response off

on

off

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6000 5900 5800 5700 5600 0

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FIGURE 1.31 An early set of fMRI images showing activation of the human visual cortex.

The Book in Your Hands | 19 draw from the wealth of brain imaging data that has been amassed in the last 30 years in our quest to learn about how the brain enables the mind.

The Book in Your Hands Our goals in this book are to introduce you to the big questions and discussions in cognitive neuroscience and to teach you how to think, ask questions, and approach those questions like a cognitive neuroscientist. In the next chapter, we introduce the biological foundations of the brain by presenting an overview of its cellular mechanisms and neuroanatomy. In Chapter 3 we discuss the methods that are available to us for observing mind– brain relationships, and we introduce how scientists go

about interpreting and questioning those observations. Building on this foundation, we launch into the core processes of cognition: hemispheric specialization, sensation and perception, object recognition, attention, the control of action, learning and memory, emotion, and language, devoting a chapter to each. These are followed by chapters on cognition control, social cognition, and a new chapter for this edition on consciousness, free will, and the law. Each chapter begins with a story that illustrates and introduces the chapter’s main topic. Beginning with Chapter 4, the story is followed by an anatomical orientation highlighting the portions of the brain that we know are involved in these processes, and a description of what a deficit of that process would result in. Next, the heart of the chapter focuses on a discussion of the cognitive process and what is known about how it functions, followed by a summary and suggestions for further reading for those whose curiosity has been aroused.

Summary Thomas Willis first introduced us, in the mid 1600s, to the idea that damage to the brain could influence behavior and that the cerebral cortex might indeed be the seat of what makes us human. Phrenologists expanded on this idea and developed a localizationist view of the brain. Patients like those of Broca and Wernicke later supported the importance of specific brain locations on human behavior (like language). Ramón y Cajal, Sherrington, and Brodmann, among others, provided evidence that although the microarchitecture of distinct brain regions could support a localizationist view of the brain, these areas are interconnected. Soon scientists began to realize that the integration of the brain’s neural networks might be what enables the mind. At the same time that neuroscientists were researching the brain, psychologists were studying the mind. Out of the philosophical theory of empiricism came the idea of associationism, that any response followed by a reward would be maintained and that these associations were the basis of how the mind learned. Associationism was the prevailing

theory for many years, until Hebb emphasized the biological basis of learning, and Chomsky and Miller realized that associationism couldn’t explain all learning or all actions of the mind. Neuroscientists and psychologists both reached the conclusion that there is more to the brain than just the sum of its parts, that the brain must enable the mind—but how? The term cognitive neuroscience was coined in the late 1970s because fields of neuroscience and psychology were once again coming together. Neuroscience was in need of the theories of the psychology of the mind, and psychology was ready for a greater understanding of the working of the brain. The resulting marriage is cognitive neuroscience. The last half of the 20th century saw a blossoming of interdisciplinary research that produced both new approaches and new technologies resulting in noninvasive methods of imaging brain structure, metabolism, and function. So welcome to cognitive neuroscience. It doesn’t matter what your background is, you’re welcome here.

Key Terms aggregate field theory (p. 7) associationism (p. 12) behaviorism (p. 13) cognitive neuroscience (p. 4)

20

cytoarchitectonics (p. 8) empiricism (p. 10) Montreal procedure (p. 13) neuron doctrine (p. 9)

phrenology (p. 6) rationalism (p. 10) syncytium (p. 9)

Thought Questions 1.

Can we study how the mind works without studying the brain?

3.

How do you think the brain might be studied in the future?

2.

Will modern brain-imaging experiments become the new phrenology?

4.

Why do good ideas and theories occasionally get lost over the passage of time? How do they often get rediscovered?

Suggested Reading Kass-Simon, G., & Farnes, P. (1990). Women of science: Righting the record. Bloomington: Indiana University Press. Lindzey, G. (Ed.). (1936). History of psychology in autobiography (Vol. 3). Worcester, MA: Clark University Press. Miller, G. (2003). The cognitive revolution: A historical perspective. Trends in Cognitive Sciences, 7, 141–144.

Raichle, M. E. (1998). Behind the scenes of functional brain imaging: A historical and physiological perspective. Proceedings of the National Academy of Sciences, USA, 95, 765–772. Shepherd, G. M. (1991). Foundations of the neuron doctrine. New York: Oxford University Press. Zimmer, C. (2004). Soul made flesh: The discovery of the brain—and how it changed the world. New York: Free Press.

21

You shake my nerves and you rattle my brain. Jerr y Lee Lewis

Structure and Function of the Nervous System

chapter

2

ONE DAY IN 1963, neuroscientist Jose Delgado coolly stood in a bullring in Cordoba, Spain, facing a charging bull. He did not sport the Spanish matador’s typical gear of toreador pants, jacket, and sword, however. No theoretical scientist he, Delgado stepped into the ring in slacks and a pullover sweater while holding a small device in his hand (and a cape, for good effect). He was about to see if it worked. As the bull came charging toward him, Delgado stood his ground, trigger finger itchy on the deOUTLINE vice’s button. And then he calmly pushed it. The bull slammed on the brakes and The Structure of Neurons skidded to a stop, standing a few feet before the scientist (Figure 2.1). The bull placidly looked at the smiling Delgado. Seemingly, this was no ordinary bull; but Neuronal Signaling yet it was. One odd thing about this bull, however, gave Delgado his confidence: Synaptic Transmission An electric stimulator had been surgically implanted in its caudate nucleus. The The Role of Glial Cells device in Delgado’s hand was a transmitter he had built to activate the stimulator. By stimulating the bull’s caudate nucleus, Delgado had turned off its aggression. The Bigger Picture Years before, Delgado had been horrified by the increasingly popular frontal Overview of Nervous System lobotomy surgical procedure that destroyed brain tissue and function. He was Structure interested in finding a more conservative approach to treating mental disorders through electrical stimulation. Using his knowledge of the electrical nature of neuA Guided Tour of the Brain rons, neuroanatomy, and brain function, he designed his devices, the first neural The Cerebral Cortex implants ever to be used. Exceedingly controversial at the time, his devices were the forerunners of the now common intracranial devices used for stimulating the Development of the Nervous System brain to treat disorders like Parkinson’s disease, chronic pain, and other maladies. Delgado understood that our nervous system uses electrochemical energy for communication and that nerves can be thought of as glorified electrical cables running to and from our brains. He also understood that inside our brains, neurons form an intricate wiring pattern: An electrical signal initiated at one location could travel to another location to trigger a muscle to contract or initiate a behavior, such as aggression, to arise or cease. Delgado was banking on the hope that he had figured out the correct circuit involved in aggressive behavior. Delgado’s device was built with the knowledge that neurons use electrochemical signals to communicate. This knowledge is the foundation on which all theories of neuronal signaling are built. Thus, for us, it is important to understand the basic physiology of neurons and the anatomy of the nervous system, which is what this chapter discusses. In many of the following chapters, we will look at what 23

24 | CHAPTER 2

Structure and Function of the Nervous System together into circuits that form the brain and extend out to form the entire nervous system. We survey the anatomy and functions of the brain and the nervous system. Finally, we look at the development of the nervous system— prenatally, in the years following birth, and in adults.

The Structure of Neurons

FIGURE 2.1 Jose Delgado halting a charging bull by remote control.

results from the activity within and among specific circuits (i.e., perception, cognition, emotion, action). Since all theories of how the brain enables the mind must ultimately mesh with the actual nuts and bolts of the nervous system, we need to understand the basics of its organizational structure, function, and modes of communication. In this chapter, we begin with the anatomy of the neuron and an overview of how information is transferred both within a neuron, and from one neuron to the next. Then, we turn to the bigger picture. Our neurons are strung

The nervous system is composed of two main classes of cells: neurons and glial cells. Neurons are the basic signaling units that transmit information throughout the nervous system. As Ramón y Cajal and others of his time deduced, neurons take in information, make a “decision” about it following some relatively simple rules, and then, by changes in their activity levels, pass it along to other neurons. Neurons vary in their form, location, and interconnectivity within the nervous system (Figure 2.2), and these variations are closely related to their functions. Glial cells are nonneural cells that serve various functions in the nervous system, some of which are only now being elucidated. These include providing structural support and electrical insulation to neurons, and modulating neuronal activity. We begin with a look at neuronal structure and function, and then we return to glial cells. The standard cellular components found in almost all eukaryotic cells are found in neurons as well. A cell membrane encases the cell body (in neurons, it is sometimes called the

FIGURE 2.2 Mammalian neurons show enormous anatomical variety. (Clockwise from upper left) Neuron from the vestibular area of the brain—glial cells are the thin white structures (confocal light micrograph); Hippocampal neuron (fluorescent micrograph); Mouse neuron and spinal cord ganglia (transmission electron micrograph); Multipolar neuron cell body from human cerebral cortex (scanning electron micrograph); Neuron from the brain; Nerve culture from dorsal root ganglia of an embryonic rat (fluorescent micrograph).

The Structure of Neurons | 25 Mitochondria

Endoplasmic reticulum

Nucleus

Dendrites

FIGURE 2.3 Idealized mammalian neuron. A neuron is composed of three main parts: a cell body, dendrites, and an axon. The cell body contains the cellular machinery for the production of proteins and other cellular macromolecules. Like other cells, the neuron contains a nucleus, endoplasmic reticulum, ribosomes, mitochondria, Golgi apparatus, and other intracellular organelles (inset). The dendrites and axon are extensions of the cell membrane and contain cytoplasm continuous with that in the cell body.

Ribosomes

Axon

Axon terminals

soma; Greek for “body”), which contains the metabolic machinery that maintains the neuron: a nucleus, endoplasmic reticulum, a cytoskeleton, mitochondria, Golgi apparatus, and other common intracellular organelles (Figure 2.3). These structures are suspended in cytoplasm, the salty intracellular fluid that is made up of a combination of ions, predominantly ions of potassium, sodium, chloride, and calcium, as well as molecules such as proteins. The neuron, like any other cell, sits in a bath of salty extracellular fluid, which is also made up of a mixture of the same types of ions.

Dendrites a

Golgi apparatus

Cell body

Neurons, unlike other cells, possess unique cytological features and physiological properties that enable them to transmit and process information rapidly. The two predominant cellular components unique to neurons are the dendrites and axon. Dendrites are branching extensions of the neuron that receive inputs from other neurons. They take many varied and complex forms, depending on the type and location of the neuron. The arborizations may look like the branches and twigs of an old oak tree, as seen in the complex dendritic structures of the cerebellar Purkinje cells (Figure 2.4),

Axon b

FIGURE 2.4 Soma and dendritic tree of a Purkinje cell from the cerebellum. The Purkinje cells are arrayed in rows in the cerebellum. Each one has a large dendritic tree that is wider in one direction than the other. (a) Sagittal section through a cerebellar cortex showing a Purkinjecell. (b) Confocal micrograph of a Purkinje cell from mouse cerebellum. The cell is visualized using flourescence methods.

26 | CHAPTER 2

Structure and Function of the Nervous System

Dendrites

Axon

a

b

FIGURE 2.5 Spinal motor neuron. (a) Neurons located in the ventral horn of the spinal cord send their axons out the ventral root to make synapses on muscle fibers. (b) A spinal cord motor neuron stained with cresyl echt violet stain.

or they may be much simpler, such as the dendrites in spinal motor neurons (Figure 2.5). Many dendrites also have specialized processes called spines, little knobs attached by small necks to the surface of the dendrites, where the dendrites receive inputs from other neurons (Figure 2.6). The axon is a single process that extends from the cell body. This structure represents the output side of the neuron. Electrical signals travel along the length of the axon to its end, the axon terminals, where the

neuron transmits the signal to other neurons or other cell types. Transmission occurs at the synapse, a specialized structure where two neurons come into close contact so that chemical or electrical signals can be passed from one cell to the next. Some axons branch to form axon collaterals that can transmit signals to more than one cell (Figure 2.7). Many axons are wrapped in layers of a fatty substance called myelin. Along the length of the axons, there are evenly spaced gaps in the myelin. These gaps are commonly referred to as the nodes of Ranvier (see Figure 2.11), named after the French histologist and anatomist Louis-Antoine Ranvier, who first described them. Later, when we look at how signals move down an axon, we will explore the role of myelin and the nodes of Ranvier in accelerating signal transmission.

TAKE-HOME MESSAGES ■ ■

FIGURE 2.6 Dendritic spines on cultured rat hippocampal neurons. Neuron has been triple stained to reveal the cell body (blue), dendrites (green), and the spines (red).

Neurons and glial cells make up the nervous system. Neurons are the cells that transmit information throughout the nervous system. Most neurons consist of a cell soma (body), axon, and dendrites. Neurons communicate with other neurons and cells atspecialized structures called synapses, where chemical and electrical signals can be conveyed between neurons.

Neuronal Signaling | 27

FIGURE 2.7 Axons can take different forms. A neuron and its axon collaterals are shown stained in yellow. The cell body (far right) gives rise to an axon, which branches forming axon collaterals that can make contact with many different neurons.

Neuronal Signaling Neurons receive, evaluate, and transmit information. This process is referred to as neuronal signaling. Information is transferred across synapses from one neuron to the next, or from a neuron to a non-neuronal cell such as those in muscles or glands. It is also conveyed within a neuron, being received at synapses on dendrites, conducted within the neuron, transmitted down the axon, and passed along at synapses on the axon terminals. These two types of transport, within and between neurons, are typically handled in different ways. Within a neuron, transferring information involves changes in the electrical state of the neuron as electrical currents flow through the volume of the neuron. Between neurons, information transfer occurs at synapses, typically mediated by chemical signaling molecules (neurotransmitters) but, in some cases, also by electrical signals. Regarding information flow, neurons are referred to as either presynaptic or postsynaptic in relation to any particular synapse. Most neurons are both presynaptic and postsynaptic: They are presynaptic when their axon makes a connection onto other neurons, and postsynaptic when other neurons make a connection onto their dendrites.

The Membrane Potential The process of signaling has several stages. Let’s return to Delgado’s bull, because his neurons process information in the same way ours do. The bull may have been snorting about in the dirt, his head down, when suddenly a sound wave—produced by Delgado entering the ring—courses down his auditory canal and hits his tympanic membrane (eardrum). The resultant stimulation of the auditory

receptor cells (auditory hair cells) generates neural signals that are transmitted via the auditory pathways to the brain. At each stage of this ascending auditory pathway, neurons receive inputs on their dendrites that typically cause them to generate signals that are transmitted to the next neuron in the pathway. How does the neuron generate these signals, and what are these signals? To answer these questions, we have to understand several things about neurons. First, energy is needed to generate the signals; second, this energy is in the form of an electrical potential across the neuronal membrane. This electrical potential is defined as the difference in the voltage across the neuronal membrane, or put simply, the voltage inside the neuron versus outside the neuron. Third, these two voltages depend on the concentrations of potassium, sodium, and chloride ions as well as on charged protein molecules both inside and outside of the cell. Fourth, when a neuron is not actively signaling—what we call its resting state—the inside of a neuron is more negatively charged than the outside. The voltage difference across the neuronal membrane in the resting state is typically −70 millivolts (mV) inside, which is known as the resting potential or resting membrane potential. This electrical potential difference means that the neuron has at its disposal a kind of battery; and like a battery, the stored energy can be used to do work— signaling work (Figure 2.8). How does the neuron generate and maintain this resting potential, and how does it use it for signaling? To answer these questions about function, we first need to examine the structures in the neuron that are involved in signaling. The bulk of the neuronal membrane is a bilayer of fatty lipid molecules that separates the cytoplasm from the extracellular milieu. Because the membrane is composed of lipids, it does not dissolve in the

28 | CHAPTER 2

Structure and Function of the Nervous System

Amplifier +

Voltage

Oscilloscope screen

Time at which electrode enters neuron

+ 0 mV

Signal is the electrical potential across the neuronal membrane.

– –70 mV Electrode enters neuron

Extracellular reference electrode

Time

Extracellular space

Na+/ K+ pump

[Cl–]

[Na+] [K+]

3

Na+ Na+

Nongated K+ channel Nongated Na+ channel

2 K+

ATP

K+

[A–]

K+

Intracellular fluid

Membrane

ADP + Pi

[ Na+]

[Cl-]

[K+]

FIGURE 2.8 Ion channels in a segment of neuronal membrane and measuring resting membrane potential. Idealized neuron (left) shown with intracellular recording electrode penetrating the neuron. The electrode measures the difference between the voltage inside versus outside the neuron and this difference is amplified and displayed on an oscilloscope screen (top). The oscilloscope screen shows voltage over time, and shows that prior to the electrode entering the neuron, voltage between the electrode and the extracellular reference electrode is zero, but when the electrode is pushed into the neuron, the difference becomes –70 mV, which is the resting membrane potential. The resting membrane potential arises from the asymmetric distribution of ions of sodium (Na+), potassium (K+), and chloride (Cl–), as well as of charged protein molecules (A–), across the neuron's cell membrane (inset).

watery environments found inside and outside of the neuron. The lipid membrane blocks the flow of watersoluble substances between the inside and the outside of the neuron. It also prevents ions (molecules or atoms that have either a positive or negative electrical charge), proteins, and other water-soluble molecules from moving across it. To understand neuronal signaling, we must focus on ions. This point is important: The lipid membrane maintains the separation of intracellular and extracellular ions and electrical charge that ultimately permits neuronal communication.

The neuronal membrane, though, is not merely a lipid bilayer. The membrane is peppered with transmembrane proteins that serve as conduits for ions to move across the neuronal membrane (Figure 2.8, inset). There are two main types of these proteins: ion channels and ion pumps. Ion channels, as we shall see, are proteins with a pore through their centers, and they allow certain ions to flow down their concentration gradients. Ion pumps use energy to actively transport ions across the membrane against their concentration gradients, that is, from regions of low concentration to regions of higher concentration.

Neuronal Signaling | 29

Ion Channels The transmembrane passageways created by ion channels are formed from the three-dimensional structure of these proteins. These hydrophilic channels selectively permit one type of ion to pass through the membrane. The ion channels of concern to us—the ones found in neurons—are selective for either sodium, potassium, calcium, or chloride ions (Na+, K+, Ca2+, and Cl−, respectively; Figure 2.8, inset). The extent to which a particular ion can cross the membrane through a given ion channel is referred to as its permeability. This characteristic of ion channels gives the neuronal membrane the attribute of selective permeability. (Selective permeability is actually a property of all cells in the body; as part of cellular homeostasis, it enables cells to maintain internal chemical stability.) The neuronal membrane is more permeable to K+ than to Na+ (or other) ions, a property that contributes to the resting membrane potential, as we shall learn shortly. The membrane permeability to K+ is larger because there are many more K+-selective channels than any other type of ion channel. Unlike most cells in the body, neurons are excitable, meaning that they can change the permeability of their membranes. This is brought about by ion channels that are capable of changing their permeability for a particular ion. Such proteins are called gated ion channels. They open or close based on changes in nearby transmembrane voltage, or as a response to chemical or physical stimuli. In contrast, ion channels that are unregulated, and hence always allow the associated ion to pass through, are known as nongated ion channels.

Ion Pumps Under normal conditions, there are concentration gradients of different ions across the neuronal membrane. Specifically, Na+ and Cl− concentrations are greater outside of the cell, and K+ concentrations are greater inside the cell. Given that the neuronal membrane contains ion channels that permit the different ions inside and outside of the cell to flow across the neuronal membrane, how does the neuron maintain different concentrations of ions inside compared with outside of the cell? Put another way, why don’t K+ ions flow out of the neuron—down their concentration gradient—until the K+ ion concentrations inside and outside the cell are equal? We can ask the same questions for all other ions. To combat this drive toward equilibrium, neurons use active transport proteins, known as ion pumps. In particular, neurons use a Na+/K+ pump that pumps Na+ ions out of the cell and K+ ions into the cell. Because this process is transporting ions up their concentration gradients, the mechanism requires energy. Each pump is an enzyme that hydrolyzes adenosine triphosphate (ATP). For each molecule of ATP that is hydrolyzed, the resulting energy is used to move three Na+ ions out of the cell and two K+ ions into the cell

Extracellular space

Na+ Na+

K+

Na+ Na+

K+

Na+ Na+

K+

K+

ATP ADP

+

Pi

Intracellular fluid FIGURE 2.9 Ion channels pump ions across the membrane. The Na+–K+ pump preserves the cell’s resting potential by maintaining a larger concentration of K+ inside the cell and Na+ outside the cell. The pump uses ATP as energy.

(Figures 2.8, inset and 2.9). The concentration gradients create forces—the forces of the unequal distribution of ions. The force of the Na+ concentration gradient wants to push Na+ from an area of high concentration to one of low concentration (from outside to inside), while the K+ concentration gradient acts to push K+ from an area of high concentration to an area of low concentration (from inside to outside)—the very thing the pump is working against. Since there are both positively and negatively charged ions inside and outside the cell, why is there a difference in voltage inside versus outside the neuron? The inside and outside voltages are different because the membrane is more permeable to K+ than to Na+. The force of the K+ concentration gradient pushes some K+ out of the cell, leaving the inside of the neuron slightly more negative than the outside. This creates another force, an electrical gradient, because each K+ ion carries one unit of positive charge out of the neuron as it moves across the membrane. These two gradients (electrical and ionic concentration) are in opposition to one another with respect to K+ (Figure 2.10). As negative charge builds up along the inside of the membrane (and an equivalent positive charge forms along the extracellular side), the positively charged K+ ions outside of the cell are drawn electrically back into the neuron through the same ion channels that are allowing K+ ions to leave the cell by diffusion. Eventually, the force of the concentration gradient pushing K+ out through the K+ channels is equal to the force of the electrical gradient driving K+ in. When that happens, the opposing forces are said to reach electrochemical equilibrium. The difference in charge thus produced across the membrane is the resting membrane potential, that −70 mV difference. The value for the resting membrane potential of any cell can be calculated by using knowledge from electrochemistry, provided that the concentrations of the ions inside and outside the neuron are known.

30 | CHAPTER 2

Structure and Function of the Nervous System

transmit the signal to another cell (your toes would be in trouble, for example, because they are + Na+ Na Na+/K+ pump Nongated K+ channel 1 meter from the spinal cord and Na+ close to 2 meters from the brain). Nongated Na+ channel K+ + How does the neuron solve this K problem of decremental conducPositive charge on + + + + + tion and the need to conduct over + extracellular side + + + + of the membrane long distances? + + Neurons evolved a clever mechanism to regenerate and _ _ _ _ pass along the signal initiated in _ _ _ _ _ _ the synapse. It works something _ _ Negative charge on like 19th-century firefighters in K+ intracellular side a bucket brigade, who handed K+ of the membrane Na+ buckets of water from one person to the next along a distance from Intracellular fluid the source of water to where it was needed at the fire. This regeneraFIGURE 2.10 Selective permeability of the membrane. The membrane’s selective permeability to some ions, and the concentration gradients formed tive process is an active membrane by active pumping, lead to a difference in electrical potential across the membrane; this is the mechanism known as the action resting membrane potential. The membrane potential, represented here by the positive charges potential. An action potential is outside the neuron along the membrane and the negative charges inside along the membrane, is a rapid depolarization and repothe basis for the transmembrane voltage difference shown in Figure 2.8. Because the concentralarization of a small region of the + + tion gradient for K forces K out of the cell, a net negative charge develops inside the neuron. membrane caused by the opening and closing of ion channels. An action potential is an entirely different animal from the EPSP. Unlike a postsynaptic potential, it doesn’t We now understand the basis of the energy source that decrement after only 1 millimeter. Action potentials can neurons can use for signaling. Next we want to learn how travel for meters with no loss in signal strength, because this energy can be used to transmit information within a they continuously regenerate the signal. This is one reaneuron, from its dendrites that receive inputs from other son there can be giraffes and blue whales. It is, however, neurons, to its axon terminals where it makes synapses metabolically expensive, and it contributes to the inordion the next neurons in the chain. The process begins nate amount of the body’s energy used by the brain. when excitatory postsynaptic potentials (EPSPs) at synapsThe action potential is able to regenerate itself due es on the neuron’s dendrites cause ionic currents to flow to the presence of voltage-gated ion channels located in the volume of the cell body. If these currents are strong in the neuronal membrane (Figure 2.11a, inset). These enough to reach the axon terminals, then the processes are found at the spike-triggering zone in the axon of neuronal signaling could be completed. Unfortunately, hillock and along the axon. In myelinated axons, these in the vast majority of cases, this distance is too great for voltage-gated ion channels are confined to the axon hillthe EPSP to have any effect. Why is this the case? ock and the nodes of Ranvier (Figure 2.11a). As its name The small electrical current produced by the EPSP is denotes, the spike-triggering zone initiates the action passively conducted through the cytoplasm of the denpotential. (The term spike is shorthand for an action drite, cell body, and axon. Passive current conduction is potential, because when viewed as a recording displayed called electrotonic conduction or decremental conduction. on an oscilloscope screen, the action potential looks like Decremental, because it diminishes with distance from its a little spike in the recorded signal.) How does the spikeorigin—the synapse, in this case. The maximum distance triggering zone initiate an action potential? a passive current will flow is only about 1 millimeter. In The passive electrical currents that are generated folmost cases, a millimeter is too short to be effective for conlowing EPSPs on multiple distant dendrites sum together ducting electrical signals, but in a structure like the retina, at the axon hillock. This current flows across the neuroa millimeter is enough to permit neuron-to-neuron comnal membrane in the spike-triggering zone, depolarizing munication. Most of the time, however, the reduction in the membrane. If the depolarization is strong enough, signal intensity makes it unlikely that a single EPSP will meaning the membrane moves from its resting potential be enough to trigger the firing of its own cell, much less of about −70 mV to a less negative value of approximately Extracellular space

The Action Potential

Neuronal Signaling | 31

Pore closed ++ ++ ++ + ++

++ ++ ++ + ++

Pore open

+++ + + + ++ +

Axon hillock

+ + + ++ + + + +

Membrane potential (mV)

Ion

20 3

gNa 20

–20 gK

–40

10

Threshold

1

–60 0 –80

Myelin sheath

a

30

2

Ionic conductance (g) in mmho/cm2

40

40

Nodes of Ranvier

Axon

Resting potential 0

1

5 4

2 Time (msec)

3

4

b

FIGURE 2.11 The neuronal action potential, voltage-gated ion channels, and changes in channel conductance. (a) An idealized neuron with myelinated axon and axon terminals. Voltage-gated ion channels located in the spike-triggering zone at the axon hillock, and along the extent to the axon, open and close rapidly, changing their conductance to specific ions (e.g., Na+), alerting the membrane potential and resulting in the action potential (inset). (b) Relative time course of changes in membrane voltage during an action potential, and the underlying causative changes in membrane conductance to Na+ (g Na) and K+ (g K). The initial depolarizing phase of the action potential (red line) is mediated by increased Na+ conductance (black line), and the later repolarizing, descending phase of the action potential is mediated by an increase in K+ conductance (dashed line) that occurs when the K+ channels open. The Na+ channels have closed during the last part of the action potential, when repolarization by the K+ current is taking place. The action potential undershoots the resting membrane potential at the point where the membrane becomes more negative than the resting membrane potential.

−55 mV, an action potential is triggered. We refer to this depolarized membrane potential value as the threshold for initiating an action potential. Figure 2.11b illustrates an idealized action potential. The numbered boxes in the figure correspond to the numbered events in the next paragraph. Each event alters a small region of the membrane’s permeability for Na+ and K+ due to the opening and closing of voltage-gated ion channels. When the threshold (Figure 2.11 b, label 1) is reached, voltage-gated Na+ channels open and Na+ flows rapidly into the neuron. This influx of positive ions further depolarizes the neuron, opening additional voltage-gated Na+ channels; thus, the neuron becomes more depolarized (2), continuing the cycle by causing even more Na+ channels to open. This process is called the Hodgkin–Huxley cycle. This rapid, self-reinforcing cycle, lasting only about 1 millisecond, generates the large depolarization that is the first portion of the action potential. Next, the voltagegated K+ channels open, allowing K+ to flow out of the neuron down its concentration gradient. This outward flow of positive ions begins to shift the membrane potential back toward its resting potential (3). The opening of the K+ channels outlasts the closing of the Na+ channels, causing a second repolarizing phase of the action potential; and this drives the membrane potential toward the equilibrium potential of K+, which is even more negative

than the resting potential. The equilibrium potential is the particular voltage at which there is no net flux of ions. As a result, (4) the membrane is temporarily hyperpolarized, meaning that the membrane potential is even farther from the threshold required for triggering an action potential (e.g., around −80 mV). Hyperpolarization causes the K+ channels to close, resulting in (5) the membrane potential gradually returning to its resting state. During this transient hyperpolarization state, the voltage-gated Na+ channels are unable to open, and another action potential cannot be generated. This is known as the absolute refractory period. It is followed by the relative refractory period, during which the neuron can generate action potentials, but only with larger-than-normal depolarizing currents. The refractory period lasts only a couple of milliseconds and has two consequences. One is that the neuron’s speed for generating action potentials is limited to about 200 action potentials per second. The other is that the passive current that flows from the action potential cannot reopen the ion-gated channels that generated it. The passive current, however, does flow down the axon with enough strength to depolarize the membrane a bit farther on, opening voltage-gated channels in this next portion of the membrane. The result is that the action potential is propagated down the axon in one direction only—from the axon hillock toward the axon terminal.

32 | CHAPTER 2

Structure and Function of the Nervous System

So that is the story of the self-regenerating action potential as it propagates itself down an axon (sometimes traveling several meters). But traveling far is not the end of the story. Action potentials must also travel quickly if a person wants to run, or a bull wants to charge, or a very large animal (think blue whale) simply wants to react in a reasonable amount of time. Accelerated transmission of the action potential is accomplished in myelinated axons. The thick lipid sheath of myelin (Figure 2.11a) surrounding the membrane of myelinated axons makes the axon superresistant to voltage loss. The high electrical resistance allows passive currents generated by the action potential to be shunted farther down the axon. The result is that action potentials do not have to be generated as often, and they can be spread out along the axon at wider intervals. Indeed, action potentials in myelinated axons need occur only at the nodes of Ranvier, where myelination is interrupted. This creates the appearance that the action potential is jumping down the axon at great speed, from one node of Ranvier to the next. We call this saltatory conduction. (Saltatory conduction is derived from the Latin word saltare, to jump or leap.) The importance of myelin for efficient neuronal conduction is notable when it is lost, which is what happens when a person is afflicted with multiple sclerosis (MS). There is one interesting tidbit left concerning action potentials. Action potentials are always the same amplitude; therefore, they are said to be all or none phenomena. Since one action potential is the same amplitude as any other, the strength of the action potential does not communicate anything about the strength of the stimulus. The intensity of a stimulus (e.g., a sensory signal) is communicated by the rate of firing of the action potentials: More intense stimuli elicit higher action potential firing rates. So, we see how the neuron has solved the problem of long-distance communication as well as communication speed. When the action potential reaches the axon terminal, the signal is now strong enough to cause depolarization of the presynaptic membrane and to trigger neurotransmitter release. The signal is ready to be transferred to the next neuron across the synaptic cleft, the gap between neurons at the synapse.

TAKE-HOME MESSAGES ■

The presynaptic cell is located before the synapse with respect to information flow; the postsynaptic cell is located after the synapse with respect to information flow. Nearly all neurons are both pre- and postsynaptic, since they both receive and transmit information. The resting membrane potential is the difference in the voltage across the neuronal membrane during rest (i.e.,not during any phase of the action potential). The electrical gradient results from the asymmetrical distribution of ions across the membrane. The electrical

difference across the membrane is the basis of the resting potential. Ion channels are formed by transmembrane proteins that create passageways through which ions can flow. Ion channels can be either passive (always open) or gated (open only in the presence of electrical, chemical, or physical stimuli). Passive current conduction is called electrotonic conduction or decremental conduction. A depolarizing current makes the inside of the cell more positive and therefore more likely to generate an action potential; a hyperpolarizing current makes the inside of the cell less positive and therefore less likely to generate an action potential. Action potentials are an all-or-none phenomena: The amplitude of the action potential does not depend on the size of the triggering depolarization, as long as that depolarization reaches threshold for initiating the action potential. Voltage-gated channels are of prime importance in generating an action potential because they open and close according to the membrane potential. Myelin allows for the rapid transmission of action potentials down an axon. Nodes of Ranvier are the spaces between sheaths of myelin where voltage-gated Na+ and K+ channels are located and action potentials occur.

Synaptic Transmission A neuron communicates with other neurons, muscles, or glands at a synapse, and the transfer of a signal from the axon terminal to the next cell is called synaptic transmission. There are two major kinds of synapses— chemical and electrical—each using very different mechanisms for synaptic transmission.

Chemical Transmission Most neurons send a signal to the cell across the synapse by releasing neurotransmitters into the synaptic cleft. The general mechanism is as follows. The arrival of the action potential at the axon terminal leads to the depolarization of the terminal membrane, causing voltage-gated Ca2+ channels to open. The opening of these channels triggers small vesicles containing neurotransmitter to fuse with the membrane at the synapse and release the transmitter into the synaptic cleft. The transmitter diffuses across the cleft and, on reaching the postsynaptic membrane, binds with specific receptors embedded in the postsynaptic membrane (Figure 2.12). Neurotransmitter binding induces a change in the receptor, which opens specific ion channels and results in an influx of ions leading to either depolarization (excitation) or hyperpolarization (inhibition) of the postsynaptic cell (Figure 2.13). Hyperpolarization of the postsynaptic neuron produces an inhibitory postsynaptic potential (IPSP).

Synaptic Transmission | 33

Neurotransmitters The process just described brings us to a hot topic of the popular press: neurotransmitters. While you may have heard of a few of them, more than 100 neurotransmitters have been identified. What makes a molecule a neurotransmitter? ■

It is synthesized by and localized within the presynaptic neuron, and stored in the presynaptic terminal before release. It is released by the presynaptic neuron when action potentials depolarize the terminal (mediated primarily by Ca2+). The postsynaptic neuron contains receptors specific for the neurotransmitter. When artificially applied to a postsynaptic cell, the neurotransmitter elicits the same response that stimulating the presynaptic neuron would.

1

rotransmitters are amino acids: aspartate, gamma-aminobutyric acid (GABA), glutamate, and glycine. Another category of neurotransmitters, called biogenic amines, includes dopamine, norepinephrine, and epinephrine (these three are known as the catecholamines), serotonin (5-hydroxytryptamine), and histamine. Acetylcholine (ACh) is a wellstudied neurotransmitter that is in its own biochemical class. Another large group of neurotransmitters consists of slightly larger molecules, the neuropeptides (made up of strings of amino acids). More than 100 neuropeptides are active in the mammalian brain, and they are divided into five groups:

Postsynaptic neuron (spine on dendrite)

Synaptic cleft

Action potential Action potential depolarizes the terminal membrane, which causes Ca2+ to flow into the cell

2

Ca2+ causes vesicles to bind with cell membrane

Cleft Ca2+

Ca2+ Ca2+

Ca2+

Ca2+ Ca2+

Vesicles containing neurotransmitter

3

Biochemical Classification of Neurotransmitters Some neu-

Synapse

Presynaptic neuron (axon terminal)

Receptors in postsynaptic membrane

Release of neurotransmitter by exocytosis into the synaptic cleft

4

Transmitter binds with receptor

FIGURE 2.12 Neurotransmitter release at the synapse, into synaptic cleft. The synapse consists of various specializations where the presynaptic and postsynaptic membranes are in close apposition. When the action potential invades the axon terminals, it causes voltage-gated Ca2+ channels to open (1), which triggers vesicles to bind to the presynaptic membrane (2). Neurotransmitter is released into the synaptic cleft by exocytosis and diffuses across the cleft (3). Binding of the neurotransmitter to receptor molecules in the postsynaptic membrane completes the process of transmission (4).

1. Tachykinins (brain-gut peptides). This group includes substance P, which affects vasoconstriction and is a spinal neurotransmitter involved in pain. 2. Neurohypophyseal hormones. Oxytocin and vasopressin are in this group. The former is involved in

mammary functions and has been tagged the “love hormone” for its role in pair bonding and maternal behaviors; the latter is an antidiuretic hormone. 3. Hypothalamic releasing hormones. This group includes corticotropin-releasing hormone, involved

34 | CHAPTER 2

Structure and Function of the Nervous System

Before transmitter release Vm Presynaptic terminal

–70

Resting membrane potential Postsynaptic neuron After transmitter release Vm 0

Excitatory postsynaptic potential

–70

Transmitter release

FIGURE 2.13 Neurotransmitter leading to postsynaptic potential. The binding of neurotransmitter to the postsynaptic membrane receptors changes the membrane potential (Vm). These postsynaptic potentials can be either excitatory (depolarizing the membrane), as shown here, or inhibitory (hyperpolarizing the membrane).

in the stress response, and somatostatin, an inhibitor of growth hormone. 4. Opioid peptides. This group is so named for its similarity to opiate drugs, permitting the neuropeptide to bind to opiate receptors. It includes the endorphins and enkephalins. 5. Other neuropeptides. This group includes peptides that do not fit neatly into another category. Some neurons produce only one type of neurotransmitter, but others produce multiple kinds of neurotransmitters. In the latter case, the neurotransmitters may be released together or separately, depending on the conditions of stimulation. For example, the rate of stimulation by the action potential can induce the release of a specific neurotransmitter.

Functional Classification of Neurotransmitters As mentioned earlier, the effect of a neurotransmitter on the postsynaptic neuron is determined by the postsynaptic receptor rather than by the transmitter itself. That is, the same neurotransmitter released from the same presynaptic neuron onto two different postsynaptic cells might cause one to increase firing and the other to decrease firing, depending on the receptors that the

transmitter binds to. The effects of a neurotransmitter also depend on the connections of the neurons that use the transmitter. Nevertheless, neurotransmitters can be classified not only biochemically but also by the typical effect that they induce in the postsynaptic neuron. Neurotransmitters that usually have an excitatory effect include ACh, the catecholamines, glutamate, histamine, serotonin, and some of the neuropeptides. Usually inhibitory neurotransmitters include GABA, glycine, and some of the peptides. Some neurotransmitters act directly to excite or inhibit a postsynaptic neuron, but other neurotransmitters act only in concert with other factors. These are sometimes referred to as conditional neurotransmitters; that is, their action is conditioned on the presence of another transmitter in the synaptic cleft or activity in the neuronal circuit. These types of mechanisms permit the nervous system to achieve complex modulations of information processing by modulating neurotransmission.

Inactivation of Neurotransmitters after Release Following the release of neurotransmitter into the synaptic cleft and its binding with the postsynaptic membrane receptors, the remaining transmitter must be removed to prevent further excitatory or inhibitory signal transduction. This removal can be accomplished (a) by active reuptake of the substance back into the presynaptic terminal, (b) by enzymatic breakdown of the transmitter in the synaptic cleft, or (c) merely by diffusion of the neurotransmitter away from the region of the synapse or site of action (e.g., in the case of hormones that act on target cells distant from the synaptic terminals). Neurotransmitters that are removed from the synaptic cleft by reuptake mechanisms include the biogenic amines (dopamine, norepinephrine, epinephrine, histamine, and serotonin). The reuptake mechanism is mediated by active transporters, which are transmembrane proteins that pump the neurotransmitter back across the presynaptic membrane. An example of a neurotransmitter that is eliminated from the synaptic cleft by enzymatic action is ACh. The enzyme acetylcholinesterase (AChE), which is located in the synaptic cleft, breaks down ACh after it has acted on the postsynaptic membrane. In fact, special AChE stains (chemicals that bind to AChE) can be used to label AChE on muscle cells, thus revealing where motor neurons innervate the muscle. To monitor the level of neurotransmitter in the synaptic cleft, presynaptic neurons have autoreceptors. These

The Role of Glial Cells | 35 autoreceptors are located on the presynaptic terminal and bind with the released neurotransmitter, allowing the presynaptic neuron to regulate the synthesis and release of the transmitter.

synapses also have some limitations: They are much less plastic than chemical synapses, and they cannot amplify a signal (whereas an action potential that triggers a chemical synapse could cause a large release of neurotransmitter, thus amplifying the signal).

Electrical Transmission Some neurons communicate via electrical synapses. These synapses are very different from chemical synapses—in electrical synapses, no synaptic cleft separates the neurons. Instead, the neuronal membranes are touching at specializations called gap junctions, and the cytoplasms of the two neurons are essentially continuous. These gap junction channels create pores connecting the cytoplasms of the two neurons (Figure 2.14). As a result, the two neurons are isopotential (i.e., have the same electrical potential), meaning that electrical changes in one are reflected instantaneously in the other. Following the principles of electrotonic conduction, however, the passive currents that flow between the neurons when one of them is depolarized (or hyperpolarized) decrease and are therefore smaller in the postsynaptic neuron than in the presynaptic neuron. Under most circumstances, the communication is bidirectional; however, so-called rectifying synapses limit current flow in one direction, as is typical in chemical synapses. Electrical synapses are useful when information must be conducted rapidly, such as in the escape reflex of some invertebrates. Groups of neurons with these synapses can activate muscles quickly to get the animal out of harm’s way. For example, the well-known tail flip reflex of crayfishes involves powerful rectifying electrical synapses. Electrical synapses are also useful when groups of neurons should operate synchronously, as with some hypothalamic neurosecretory neurons. Electrical

Cytoplasm of presynaptic Gap junction neuron

Pore

Cytoplasm of postsynaptic neuron

FIGURE 2.14 Electrical synapse between two neurons. Electrical synapses are formed by gap junctions, places where multiple transmembrane proteins in the pre- and postsynaptic neurons connect to create pathways that connect the cytoplasms of the two neurons.

TAKE-HOME MESSAGES ■

Synapses are the locations where one neuron can transfer information to another neuron or specialized non-neuronal cell. They are found on dendrites and at axon terminals but can also be found on the neuronal cell body. Chemical transmission results in the release of neurotransmitters from the presynaptic neuron and the binding of those neurotransmitters on the postsynaptic neuron, which in turn causes excitatory or inhibitory postsynaptic potentials (EPSPs or IPSPs), depending on the properties of the postsynaptic receptor. Classes of neurotransmitters include amino acids, biogenic amines, and neuropeptides. Neurotransmitters must be removed from the receptor after binding. This removal can be accomplished by (a)active reuptake back into the presynaptic terminal, (b)enzymatic breakdown of the transmitter in the synaptic cleft, or (c) diffusion of the neurotransmitter away from the region of the synapse. Electrical synapses are different than chemical synapses as they operate by passing current directly from one neuron (presynaptic) to another neuron (postsynaptic) via specialized channels in gap junctions that connect the cytoplasm of one cell directly to theother.

The Role of Glial Cells The other type of cell in the nervous system is the glial cell (also called neuroglial cell). There are roughly as many glial cells in the brain as there are neurons. Located throughout the nervous system, they may account for more than half of the brain’s volume. The term neuroglia means, literally, “nerve glue,” because anatomists in the 19th century believed that the main role of neuroglial cells in the nervous system was structural support. While glial cells do provide structural support, they also carry out other roles in the nervous system, such as helping to form the blood–brain barrier and aiding in the speed of information transfer. More recently, glial cells have revealed a bit of a surprise: They appear to have a previously unrecognized role in modulating neural activity. The central nervous system has three main types of glial cells: astrocytes, microglial cells, and oligodendrocytes (Figure 2.15). Astrocytes are large glial cells with round

36 | CHAPTER 2

Structure and Function of the Nervous System

an active role in brain function. In vitro studies indicate that they respond to and Blood vessel release neurotransmitters and other neuroactive substances that affect neuronal Astrocyte activity and modulate synaptic strength. More recently, in vivo studies found that when astrocyte activity is blocked, neural activity increases. This finding supports the notion that neural activity is moderatCentral Axon nervous ed by astrocyte activity (Schummers et al., Oligodendrocyte system 2008). It is hypothesized that astrocytes Myelin either directly or indirectly regulate the reuptake of neurotransmitters. Microglial cells, which are small and irregularly shaped (Figure 2.15), come into play when tissue is damaged. They are Microglial cell phagocytes, literally devouring and removing damaged cells. Unlike many cells in the central nervous system, microglial cells can proliferate even in adults (as do other Peripheral glial cells). nervous Schwann cell Glial cells are also the myelin formers system Myelin in the nervous system. In the central nervous system, oligodendrocytes form myelin; Axon in the peripheral nervous system, Schwann FIGURE 2.15 Various types of glial cells in the mammalian central and peripheral cells carry out this task (Figure 2.15). Both nervous systems. glial cell types create myelin by wrapping An astrocyte is shown with end feet attached to a blood vessel. Oligodendrocytes their cell membranes around the axon in and Schwann cells produce myelin around the axons of neurons—oligodendrocytes a concentric manner during development in the central nervous system, andSchwann cells in the peripheral nervous system. and maturation. The cytoplasm in that porA microglial cell is also shown. tion of the glial cell is squeezed out, leaving primarily the lipid bilayer of the glial cell sheathing the membrane. Myelin is a good electrior radially symmetrical forms; they surround neurons cal insulator because the layers of cell membrane are and are in close contact with the brain’s vasculature. An composed of lipid bilayers, which are themselves poor astrocyte makes contact with blood vessels at specializaelectrical conductors. tions called end feet, which permit the astrocyte to transport ions across the vascular wall. The astrocytes create a barrier, called the blood–brain barrier (BBB), between the tissues of the central nervous system and the blood. TAKE-HOME MESSAGES The BBB restricts the diffusion of microscopic objects ■ An astrocyte is a type of glial cell that helps form the (such as most bacteria) and large hydrophilic molecules blood–brain barrier. in the blood from entering the neural tissue, but it allows ■ Astrocytes have an active role in modulating neural activity. the diffusion of small hydrophobic molecules such as oxy■ Glial cells aid in the speed of information transfer by gen, carbon dioxide, and hormones. For example, many forming myelin around the axons of the neurons. drugs and certain neuroactive agents, such as dopamine ■ An oligodendrocyte is a type of glial cell that forms and norepinephrine, when placed in the blood, cannot myelin in the central nervous system. ■ A Schwann cell is a type of glial cell that forms myelin in cross the BBB. Thus, it plays a vital role in protecting the the peripheral nervous system. central nervous system from blood-borne agents such as ■ As part of the immune response of the nervous system, chemical compounds, as well as pathogens that might microglial cells are phagocytic cells that engulf damaged unduly affect neuronal activity. cells. Astrocytes are recognized for their supporting roles, so to speak, but recent evidence suggests that they have

Overview of Nervous System Structure | 37

The Bigger Picture Until now, we have been talking about only one or two neurons at a time. This approach is useful in understanding how neurons transmit information, but it fails to illuminate how the nervous system and the brain function. Neurons rarely work in isolation. Neural communication depends on patterns of connectivity in the nervous system, the neural “highways” that allow information to get from one place to another. Identifying these patterns of connectivity in the nervous system in order to map out the neural highways is tricky because most neurons are not wired together in simple, serial circuits. Instead, neurons are extensively connected in both serial and parallel circuits. A single cortical neuron is likely to be innervated by (i.e., receive inputs from) a large numbers of neurons: A typical cortical neuron has between 1,000 and 5,000 synapses, while a Purkinje neuron may have up to 200,000 synapses. The axons from these input neurons can originate in widely distributed regions. Thus, there is tremendous convergence in the nervous system. There is also divergence, in which a single neuron can project to multiple target neurons in different regions. Although most axons are short projections from neighboring cortical cells, some are quite long, originating in distant cortical regions. These may reach their target only after descending below the cortical sheath into the white matter, traveling through long fiber tracts, and then entering another region of cortex, subcortical nucleus, or spinal layer to synapse on another neuron. Thanks to this extensive interconnectivity, each neuron is only a few synapses away from any other given neuron, and each neuron makes a small contribution to overall function. Connections between two cortical regions are referred to as corticocortical connections, following the convention that the first part of the term identifies the source and the second part identifies the target. Inputs that originate in subcortical structures such as the thalamus would be referred to as thalamocortical connections; the reverse are corticothalamic, or more generally, corticofugal projections (projections extending from more central structures, like cortex, outward toward the periphery). Groups of interconnected neurons that process specific kinds of information are referred to as neural circuits. Neural circuits have many different forms and purposes. Some are involved in reflexes, such as the “knee-jerk reflex”—a tap by your doctor on your patellar tendon at the knee sends a sensory signal to the spinal cord which stimulates motor neurons to fire action potentials leading to muscle contraction and the brief knee jerk. This is an example of a monosynaptic reflex arc, stimulation of which is used by all physicians to test the integrity of

different parts of the nervous system. Other neural circuits throughout the nervous system perform other functions. In general though, neural circuits share some basic features. They take in information (afferent inputs), they evaluate the input either at a synapse or within one or a group of neurons (local circuit neurons), and they convey the results to other neurons, muscles, or glands (efferent outputs). One characteristic of some neural circuits is that they show plasticity. The patterns of activation within a neural circuit can change. This is what happens with learning and during development. Neural circuits, in turn, can be combined to form neural systems. For example, the visual system is composed of many different neural circuits organized in both hierarchical and parallel processing streams to enable vision, and to provide outputs to cognitive and motor systems. Neural circuits involved in the visual system include such things as the retinogeniculostriate circuit that brings information from the eye to the visual cortex. Later in the book we will refer to visual areas, such as visual area V1, which is the striate (primary) visual cortex. Areas are intermediate between neural circuits and systems. That is, the visual system comprises neurons, neural circuits, and visual areas. But before we can talk about neural circuits, systems, areas, or anything else about the brain for that matter, we need to get some neuroanatomy under our belts. Understanding anatomy is important for understanding function. So, next we present a tour of neuroanatomy, including a bit of function to put the brain anatomy into the context of cognitive neuroscience. For a brief discussion of celebral vasculature, see the box “How the Brain Works: Blood Supply and the Brain.” Early in each of Chapters 4 through 14, there is a box called Anatomical Orientation, containing one or a few illustrations of the brain. This box highlights the anatomy that is relevant to the cognitive functions discussed in that chapter. The anatomy presented here and in the coming chapters will help you see how the structures of the brain are related to the functions of the mind.

Overview of Nervous System Structure The nervous system is composed of the central nervous system (CNS), consisting of the brain and spinal cord, and the peripheral nervous system (PNS), consisting of the nerves (bundles of axons and glia) and ganglia (clumps

38 | CHAPTER 2

Structure and Function of the Nervous System

Central nervous system (CNS)

Peripheral nervous system (PNS)

FIGURE 2.16 The peripheral and central nervous systems of the human body. The nervous system is generally divided into two main parts. The central nervous system includes the brain and spinal cord. The peripheral nervous system, comprising the sensory and motor nerves and associated nerve cell ganglia (groups of neuronal cell bodies), is located outside the central nervous system.

of nerve cell bodies) outside of the CNS (Figure 2.16). The CNS can be thought of as the command-and-control center of the nervous system. The PNS represents a courier network that delivers sensory information to the CNS and carries the motor commands from the CNS to the muscles. These activities are accomplished through two systems, the somatic motor system that controls the voluntary muscles of the body and the autonomic motor system that controls visceral functions. Before we concentrate on the CNS, a word about the autonomic nervous system.

The Autonomic NervousSystem The autonomic nervous system (also called the autonomic, or visceral, motor system) is involved in controlling the involuntary action of smooth muscles, the heart, and various glands. It has two subdivisions: the sympathetic and parasympathetic branches (Figure 2.17). The sympathetic system uses the neurotransmitter norepinephrine, and the parasympathetic system uses acetylcholine as its transmitter. The two systems frequently

operate antagonistically. For example, activation of the sympathetic system increases heart rate, diverts blood from the digestive tract to the somatic musculature, and prepares the body for action (fight or flight) by stimulating the adrenal glands to release adrenaline. In contrast, activation of the parasympathetic system slows heart rate, stimulates digestion, and in general helps the body with functions germane to maintaining the body. In the autonomic system, a great deal of specialization takes place that is beyond the scope of this chapter. Still, understanding that the autonomic system is involved in a variety of reflex and involuntary behaviors, mostly below the level of consciousness, is useful for interpreting information presented later in the book. In Chapter 10, on emotion, we will discuss arousal of the autonomic nervous system and how changes in a number of psychophysiological measures tap into emotion-related changes in the autonomic nervous system. For example, changes in skin conductance are related to sweat gland activity, and sweat glands are under the control of the autonomic nervous system. In the rest of this chapter, we focus on the CNS in order to lay the groundwork for the studies of cognition that compose the rest of the book. But to talk about brain anatomy, we need some standard terminology that places parts of the brain in proper three-dimensional space. For that, please take a look at the box “Navigating the Brain.”

The Central Nervous System The CNS is made up of the delicate brain and spinal cord, each encased in its protective, bony shell and suspended in a sea of cerebrospinal fluid (CSF). Both the brain and the spinal cord are covered with three protective membranes—the meninges. The outer membrane is the thick dura mater; the middle is the arachnoid mater ; and the inner and most delicate is the pia mater, which firmly adheres to the surface of the brain. The CSF occupies the subarachnoid space between the arachnoid membrane and the pia mater, as well as the brain ventricles, cisterns and sulci, and the central canal of the spinal cord (see “How the Brain Works: The Chambers of the Mind”). In the CNS, neurons are bunched together in various ways (Figure 2.18). Two of the most common organizational clusters are in a nucleus or in a layer. A nucleus is a relatively compact arrangement of nerve cell bodies and their connections, ranging from hundreds to millions of neurons, with functionally similar inputs and outputs. They are located throughout both the brain and the spinal cord. The outer layer of the brain, the cerebral cortex, on the other hand, has billions of neurons. They are arranged in layers of thin sheets, folded across the surfaces of the cerebral hemispheres like a

Overview of Nervous System Structure | 39 Parasympathetic branch

Sympathetic branch

Constricts pupil

Dilates pupil

Inhibits tear glands

Stimulates tear glands

Increases salivation

Inhibits salivation; increases sweating

Accelerates heart Slows heart Dilates bronchi (breathe more rapidly) Constricts bronchi (breathe less rapidly)

Decreases digestive functions of stomach and pancreas

Increases digestive functions of stomach and pancreas

Secretes adrenaline

Increases digestive functions of intestine

Chain of sympathetic ganglia

Decreases digestive functions of intestine

Spinal cord Inhibits bladder contraction

Stimulates bladder contraction Stimulates blood flow to the genital organs (erection)

Inhibits blood flow to the genitals

FIGURE 2.17 Organization of the autonomic nervous system, showing sympathetic and parasympathetic branches. Please see the text for details.

handkerchief. When we look at a slice of the brain, we see the cortex as a thin grayish layer overlaying the whitish interior. The gray matter is composed of neuronal cell bodies, and the white matter consists of axons and glial cells. Much like nerves in the PNS, these axons are grouped together in tracts that run in association tracts from one region to another within a hemisphere, or may cross into the other hemisphere in tracts called commissures. The largest of all the fiber tracts is the main commissure crossing between the hemispheres, the corpus callosum. Finally, there are projection tracts that run from the cerebral cortex to the deeper subcortical structures and the spinal cord.

■ ■

TAKE-HOME MESSAGES ■

The central nervous system consists of the brain and spinal cord. The peripheral nervous system consists of all nerves and neurons outside of the central nervous system.

The autonomic nervous system is involved in controlling the action of smooth muscles, the heart, and various glands. Itincludes the sympathetic and parasympathetic systems. The sympathetic system uses the neurotransmitter norepinephrine. This system increases heart rate, diverts blood from the digestive tract to the somatic musculature, and prepares the body for fight-or-flight responses by stimulating the adrenal glands. The parasympathetic system uses acetylcholine as a neurotransmitter. It is responsible for decreasing heart rate and stimulating digestion. Groups of neurons are called ganglia. The cerebral cortex is a continuous sheet of layered neurons in each hemisphere. The axons of cortical neurons and subcortical ganglia travel together in white matter tracts that interconnect neurons in different parts of the brain and spinal cord. The corpus callosum is the main fiber tract that connects the two hemispheres of the brain.

40 | CHAPTER 2

Structure and Function of the Nervous System

The Spinal Cord Nucleus (relatively compact arrangement of nerve cell bodies and their connections)

Cerebral cortex Grey matter (neurons arranged in layers forming a sheet of tissue)

White matter (axons and glial cells forming tracts interconnecting the brain.)

FIGURE 2.18 Organization of neurons in the CNS. In the CNS, neurons can be organized in clumps called nuclei (top—not to be confused with the nucleus inside each neuron), which are most commonly found in subcortical and spinal structures, or sheets called layers (middle), which are most commonly found in the cortex. The cell bodies of glial cells are located in the white matter (e.g., oligodendrocytes), and in the cortex.

The spinal cord takes in sensory information from the body’s peripheral sensory receptors, relays it to the brain, and conducts the final motor signals from the brain to muscles. In addition, each level of the spinal cord has reflex pathways, such as the knee-jerk reflex mentioned earlier. The spinal cord runs from the brainstem at about the first spinal vertebrae to its termination in the cauda equina (meaning “horse’s tail”). It is enclosed in the bony vertebral column—a stack of separate bones, the vertebrae, that extend from the base of the skull to the fused vertebrae at the coccyx (tailbone). The vertebral column is divided into sections: cervical, thoracic, lumbar, sacral, and coccygeal. The spinal cord is similarly divided (excluding the coccygeal region, since we no longer have tails) into 31 segments. Each segment has a right and a left spinal nerve that enters and exits from the vertebral column through openings called foramen. Each spinal nerve has both sensory and motor axons: one afferent neuron carries sensory input through the dorsal root into the spinal cord, and the other efferent neuron carries motor output through the ventral root away from it. In looking at a cross section of the spinal cord (Figure 2.19), we can see the peripheral region is made up of

Dorsal columns

A Guided Tour of theBrain

Central canal Gray matter

Dorsal horn Ventral horn Dorsal root

When we see a brain, the cerebral cortex, the outer layer, is most prominent. But for the brain, the cerebral cortex is the frosting on the cake—it’s the last thing to develop from an evolutionary, as well as an embryological, point of view. Deep within, at the base of the brain, are structures that are found in most vertebrates and have evolved for hundreds of millions of years. These parts of the brain control our most basic survival functions, such as breathing, heart rate, and temperature. In contrast, the prefrontal cortex, which is found only in mammals, is evolutionarily the youngest part of our brain. Damage to the prefrontal cortex may not be immediately fatal, but it will likely affect such things as our ability to make decisions as well as other behaviors that we consider to be most advanced in humans. We begin our tour of the CNS with a brief look at the spinal cord.

Spinal nerve

Dorsal-root ganglion

White matter Ventral root

Ventral columns

FIGURE 2.19 Gross anatomy of the spinal cord. This cross-sectional and three-dimensional representation of the spinal cord shows the central butterfly-shaped gray matter, which contains neuronal cell bodies, and the surrounding white matter axon tracts, which convey information down the spinal cord from the brain to the peripheral neurons and up the spinal cord from peripheral receptors to the brain. The dorsal and ventral nerve roots are shown exiting and entering the cord; they fuse to form peripheral nerves. The cell bodies of peripheral sensory inputs reside in the dorsal-root ganglion and project their axons into the central nervous system via the dorsal root. The ventral horn of the spinal cord houses motor neurons that project their axons out the ventral roots to innervate peripheral muscles.

A Guided Tour of theBrain | 41

THE COGNITIVE NEUROSCIENTIST’S TOOLKIT

Navigating the Brain

Rostral (anterior)

Ventral

Caudal (posterior)

Dorsal Ventral (inferior)

al str Ro l da

Dorsal

Dorsal (superior)

u Ca

For anatomists, the head is merely an appendage to the body, so the terms that are used to describe the orientation of the head and its brain are in relation to the body. Confusion arises due to differences in how the head and body are arranged in animals that walk on four legs versus humans, who are upright. Let’s first picture the body of the cutest kind of dog, an Australian shepherd, looking off to the left of the page (Figure 1, top). The front end is the rostral end, meaning “nose.” The opposite end is the caudal end, the “tail.” Along his back is the dorsal surface, just like the dorsal fin is on the back of a shark. The bottom surface along the dog’s belly is the ventral surface. We can refer to the dog’s nervous system by using the same coordinates (Figure 1, bottom). The part of the brain toward the front is the rostral end (toward the frontal lobes); the posterior end is the caudal end (toward the occipital lobe). Along the top of his head is the dorsal surface, and the bottom surface of the brain is the ventral surface. We humans are atypical animals because we stand upright and, therefore, tilt our heads forward in order to be parallel with the ground. Thus, the dorsal surface of the body and brain are now at right angles to each other (Figure 2). Luckily, we have a cerebral cortex that can understand this. In humans, we also use the terms superior and inferior to refer to the top and bottom of the brain, respectively. Similarly, along with the terms rostral, which still means “toward the frontal pole,” and caudal, which still means “toward the occipital pole,” anterior and posterior are also used to refer to the front and back of the brain, respectively.

FIGURE 2 Navigating the human brain.

When we consider the spinal cord, the coordinate systems align with the body axis. Thus, in the spinal cord, rostral means “toward the brain,” just as it does in the dog. Throughout this book, pictures of brain slices usually will be in one of three planes (Figure 3). If we slice it from nose to tail, that is a sagittal section. When that slice is directly through the middle, it is a midsagittal or medial section. If it is off to the side, it is a lateral section. If sliced from top to bottom, separating the front of the brain from the back, we have made a coronal section. If we slice in a plane that separates dorsal from ventral, that is known as either an axial, transverse, or horizontal section.

Coronal section Rostral

Caudal

Ventral

Axial, transverse, or horizontal section

Dorsal Rostral

Ventral

Caudal Do rsa l

Ve ntr al

Sagittal sections: Midsagittal section Lateral sagittal section

FIGURE 1 A dog brain in relation to the body.

FIGURE 3 Three orthogonal planes through the brain.

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Structure and Function of the Nervous System

HOW THE BRAIN WORKS

The Chambers of the Mind Scientists have understood for many decades that neurons in the brain are functional units, and that how they are interconnected yields specific circuits for the support of particular behaviors. Centuries ago, early anatomists, believing that the head contained the seat of behavior, examined the brain to see where the conscious self (soul, if you wish) was located. They found a likely candidate: Some chambers in the brain seemed to be empty (except for some fluid) and thus were possible containers for higher functions. These chambers are called ventricles (Figure 1). What is the function of these chambers within the brain? The brain weighs a considerable amount but has little or no structural support; there is no skeletal system for the brain. To overcome this potential difficulty, the brain is immersed in a fluid called cerebrospinal fluid (CSF). This fluid allows the brain to float to help offset the pressure that would be present if the brain were merely sitting on the base of the skull. CSF also reduces shock to the brain and spinal cord during rapid accelerations

or decelerations, such as when we fall or are struck on thehead. The ventricles inside the brain are continuous with the CSF surrounding the brain. The largest of these chambers are the lateral ventricles, which are connected to the third ventricle in the brain’s midline. The cerebral aqueduct joins the third to the fourth ventricle in the brainstem below the cerebellum. The CSF is produced in the lateral ventricles and in the third ventricle by the choroid plexus, an outpouching of blood vessels from the ventricular wall. Hence, CSF is similar to blood, being formed from an ultrafiltrate of blood plasma; essentially, CSF is a clear fluid containing proteins, glucose, and ions, especially potassium, sodium, and chloride. It slowly circulates from the lateral and third ventricles through the cerebral aqueduct to the fourth ventricle and on to the subarachnoid space surrounding the brain, to be reabsorbed by the arachnoid villi in the sagittal sinus (the large venous system located between the two hemispheres on the dorsal surface; not shown).

Ventricles Lateral ventricle Interventricular foramen

Third ventricle Cerebral aqueduct Fourth ventricle

Cerebellomedullary cistern (cisterna magna) FIGURE 1 Ventricles of the human brain. (left) Midsagital section showing the medial surface of the left hemisphere. (right) Transparent brain showing the ventricular system in 3D view.

white matter tracts. The more centrally located gray matter, consisting of neuronal bodies, resembles a butterfly with two separate sections or horns: the dorsal horn and ventral horn. The ventral horn contains the large motor neurons that project to muscles. The dorsal horn contains sensory neurons and interneurons. The interneurons

project to motor neurons on the same (ipsilateral) and opposite (contralateral) sides of the spinal cord to aid in the coordination of limb movements. The gray matter surrounds the central canal, which is an anatomical extension of the ventricles in the brain and contains cerebrospinal fluid.

A Guided Tour of theBrain | 43 Corpus callosum

Hypothalamus Dura mater

a

Midbrain

Pons

Medulla

Spinal cord

Cerebellum

b

FIGURE 2.20 Gross anatomy of a brain showing brain stem. (a) Midsagittal section through the head, showing the brainstem, cerebellum, and spinal cord. (b) Highresolution structural MRI obtained with a 4-tesla scanner, showing the same plane of section as in (a).

We usually think of the brainstem as having three main parts: the medulla (myelencephalon), the pons and cerebellum (metencephalon), and the midbrain (mesencephalon). These three sections form the central nervous system between the spinal cord and the diencephalon. Though the brainstem is rather small compared to the vast bulk of the forebrain (Figures 2.20 and 2.21), it plays a starring role in the brain. It contains groups of motor and sensory nuclei, nuclei of widespread modulatory neurotransmitter systems, and white matter tracts of ascending sensory information and descending motor signals. Damage to the brainstem is life threatening, largely because brainstem nuclei control respiration and global states of consciousness such as sleep and wakefulness. The medulla, pons, and cerebellum make up the hindbrain, which we look at next.

to synapse in the thalamus en route to the somatosensory cortex. Another interesting feature of the medulla is that the corticospinal motor axons, tightly packed in a pyramid-shaped bundle (called the pyramidal tract), cross here to form the pyramidal decussation. Thus, the motor neurons originating in the right hemisphere cross to control muscles on the left side of the body, and vice versa. Functionally, the medulla is a relay station for sensory and motor information between the body and brain; it is the crossroads for most of the body’s motor fibers;

Thalamus Lateral geniculate nucleus Optic nerve (II) Midbrain

The Brainstem: Medulla, Pons, Cerebellum, and Midbrain

Medulla The brainstem’s most caudal portion is the Medulla

Pons

Spinal cord

medulla, which is continuous with the spinal cord (Figure 2.21). The medulla is essential for life. It houses the cell bodies of many of the 12 cranial nerves, providing sensory and motor innervations to the face, neck, abdomen, and throat (including taste) as well as the motor nuclei that innervate the heart. The medulla controls vital functions such as respiration, heart rate, and arousal. All of the ascending somatosensory information entering from the spinal cord passes through the medulla via two bilateral nuclear groups, the gracile and cuneate nuclei. These projection systems continue through the brainstem

Trigeminal nerve (V)

Cerebellar peduncle (cerebellum removed)

Cervical roots

FIGURE 2.21 Lateral view of the brainstem showing the thalamus, pons, medulla, midbrain, and spinal cord. Anterior in the brain is at the top, and the spinal cord is toward the bottom in this left lateral view. The cerebellum is removed in this drawing.

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it controls several autonomic functions, including the essential reflexes that determine respiration, heart rate, blood pressure, and digestive and vomiting responses.

Pons The pons, Latin for “bridge,” is so named because it is the main connection between the brain and the cerebellum. Sitting anterior to the medulla, the pons is made up of a vast system of fiber tracts interspersed with nuclei (Figure 2.21). Many of the cranial nerves synapse in the pons; these include the sensory and motor nuclei from the face and mouth and the visuomotor nuclei controlling some of the extraocular muscles. Thus, the pons is important for some eye movements as well as those of the face and mouth. In addition, some auditory information is channeled through another pontine structure, the superior olive. This level of the brainstem contains a large portion of the reticular formation that modulates arousal. Interestingly, the pons is also responsible for generating rapid eye movement (REM) sleep.

Cerebellum The cerebellum (literally, “small cerebrum” or “little brain”), which clings to the brainstem at the level of the pons, is home to most of the brain’s neurons (see Figures 2.20 and 2.22). Visually, the surface of the cerebellum appears to be covered with thinly spaced, parallel grooves; but in reality, it is a continuous layer of tightly folded neural tissue (like an accordion). It forms the roof of the fourth ventricle and sits on the cerebellar peduncles (meaning “feet”), which are massive input and output fiber tracts of the cerebellum (see Figure 2.21).

The cerebellum has several gross subdivisions, including the cerebellar cortex, four pairs of deep nuclei, and the internal white matter (Figure 2.22). In this way, the cerebellum resembles the forebrain’s cerebral hemispheres. Most of the fibers arriving at the cerebellum project to the cerebellar cortex, conveying information about motor outputs and sensory inputs describing body position. Inputs from vestibular projections involved in balance, as well as auditory and visual inputs, also project to the cerebellum from the brainstem. The output from the cerebellum originates in the deep nuclei. Ascending outputs travel to the thalamus and then to the motor and premotor cortex. Other outputs project to nuclei of the brainstem, where they impinge on descending projections to the spinal cord. The cerebellum is critical for maintaining posture, walking, and performing coordinated movements. It does not directly control movements; instead, it integrates information about the body, such as its size and speed, with motor commands. Then, it modifies motor outflow to effect smooth, coordinated movements. It is because of the cerebellum that Yo-Yo Ma can play the cello and the Harlem Globetrotters can dunk a ball with such panache. If your cerebellum is damaged, your movements will be uncoordinated and halting, and you may not be able to maintain balance. In Chapter 8, we look more closely at the cerebellum’s role in motor control. In the 1990s, it was discovered that the cerebellum is involved with more than motor functions. It has been implicated in aspects of cognitive processing including language, attention, learning, and mental imagery.

Midbrain The mesencephalon, or midbrain, lies supeDeep Nuclei:

Thalamus

Fastigial nucleus

Colliculi

Interposed nuclei Dentate nucleus

FIGURE 2.22 Gross anatomy of the cerebellum. Anterior in the brain is at the top, and the spinal cord is toward the bottom (not shown). This dorsal view of the cerebellum shows the underlying deep nuclei in a see-through projection.

rior to the pons and can be seen only in a medial view. It surrounds the cerebral aqueduct, which connects the third and fourth ventricles. Its dorsal portion consists of the tectum (meaning “roof”), and its ventral portion is the tegmentum (“covering”). Large fiber tracts course through the ventral regions from the forebrain to the spinal cord, cerebellum, and other parts of the brainstem. The midbrain also contains some of the cranial nerve ganglia and two other important structures: the superior and inferior colliculi (Figure 2.23). The superior colliculus plays a role in perceiving objects in the periphery and orienting our gaze directly toward them, bringing them into sharper view. The inferior colliculus is used for locating and orienting toward auditory stimuli. Another structure, the red nucleus, is involved in certain aspects of motor coordination. It helps a baby crawl or coordinates the swing of your arms as you walk. Much of the midbrain is occupied by the mesencephalic reticular formation, a rostral continuation of the pontine and medullary reticular formation.

A Guided Tour of theBrain | 45 Massa intermedia

Thalamus Pineal body

Thalamic relays

Third ventricle Lateral geniculate nucleus

Many neurochemical systems have nuclei in the brainstem that project widely to the cerebral cortex, limbic system, thalamus, and hypothalamus. The cerebellum integrates information about the body and motor commands and modifies motor outflow to effect smooth, coordinated movements.

Superior colliculus

Medial geniculate nucleus

The Diencephalon: Thalamus and Hypothalamus

Inferior colliculus

Cranial nerve VI

After leaving the brainstem, we arrive at the diencephalon, which is made up of the thalamus and hypothalamus. These subcortical structures are composed of groups of nuclei with interconnections to widespread brain areas.

Cerebellar peduncles Fourth ventricle

Thalamus Almost smack dab in the center of the brain FIGURE 2.23 Anatomy of the midbrain. The dorsal surface of the brainstem is shown with the cerebral cortex and cerebellum removed.

TAKE-HOME MESSAGES ■

The spinal cord conducts the final motor signals to the muscles, and it relays sensory information from the body’s peripheral receptors to the brain. The brainstem’s neurons carry out many sensory and motor processes, including visuomotor, auditory, and vestibular functions as well as sensation and motor control of the face, mouth, throat, respiratory system, and heart. The brainstem houses fibers that pass from the cortex to the spinal cord and cerebellum, and sensory fibers that run from spinal levels to the thalamus and then to the cortex.

and perched on top of the brainstem (at the rostral end; see Figure 2.21), the thalamus is the larger of the diencephalon structures. The thalamus is divided into two parts—one in the right hemisphere and one in the left—that straddle the third ventricle. In most people, the two parts are connected by a bridge of gray matter called the massa intermedia (see Figure 2.23). Above the thalamus are the fornix and corpus callosum; beside it is the internal capsule, containing ascending and descending axons running between the cerebral cortex and the medulla and spinal cord. The thalamus has been referred to as the “gateway to the cortex” because, except for some olfactory inputs, all of the sensory modalities make synaptic relays in the thalamus before continuing to the primary cortical sensory receiving areas (Figure 2.24). The thalamus is involved in relaying primary sensory information. It also receives inputs from the basal ganglia, cerebellum, neocortex, and medial temporal lobe and sends projections back to these structures to create circuits involved in many different functions. It also relays

Anterior nucleus Dorsal medial

Pulvinar nucleus Dorsal lateral

To primary somatosensory cortex

Ventral posterolateral nucleus Ventral posteromedial nucleus From retina, to primary visual cortex

From ascending auditory pathway, to primary auditory cortex Medial geniculate nucleus Lateral geniculate nucleus

FIGURE 2.24 The thalamus, showing inputs and outputs and major subdivisions. The various subdivisions of the thalamus serve different sensory systems and participate in various cortical–subcortical circuits. The posterior portion of the thalamus (lower right) is cut away in cross section and separated from the rest of the thalamus to reveal the internal organization of the thalamic nuclei (upper left).

Structure and Function of the Nervous System

most of the motor information that is on its way to the spinal cord. Thus, the thalamus, a veritable Grand Central Station of the brain, is considered a relay center where neurons from one part of the brain synapse on neurons that travel to another region. In the thalamus, information can be reorganized and shuttled, like in a train station switching yard, according to the connection patterns formed by the neurons. The thalamus is divided into several nuclei that act as specific relays for incoming sensory information (Figure 2.24). The lateral geniculate nucleus receives information from the ganglion cells of the retina and sends axons to the primary visual cortex. Similarly, the medial geniculate nucleus receives information from the inner ear, via other brainstem nuclei in the ascending auditory pathway, and sends axons to the primary auditory cortex. Somatosensory information projects via the ventral posterior (medial and lateral) nuclei of the thalamus to the primary somatosensory cortex. Sensory relay nuclei of the thalamus not only project axons to the cortex but also receive heavy descending projections back from the same cortical area that they contact. Located at the posterior pole of the thalamus is the pulvinar nucleus, which is involved in attention and in integrative functions involving multiple cortical areas.

Hypothalamus The main link between the nervous system and the endocrine system is the hypothalamus, which is the main site for hormone production and control. Easily located, it lies on the floor of the third ventricle (see Figure 2.20a). The two bumps seen on the ventral surface of the brain, the mammillary bodies, belong to the small collection of nuclei and fiber tracks contained in the hypothalamus (Figure 2.25). It receives inputs from the limbic system structures and other brain areas. One of its jobs is to control circadian rhythms (light–dark cycles) with inputs from the mesencephalic reticular formation, amygdala, and the retina. Extending from the hypothalamus are major projections to the prefrontal cortex, amygdala, spinal cord, and pituitary gland. The pituitary gland is attached to the base of the hypothalamus. The hypothalamus controls the functions necessary for maintaining the normal state of the body (homeostasis). It sends out signals that drive behavior to alleviate such feelings as thirst, hunger, and fatigue, and it controls body temperature and circadian cycles. You would not want to be in the broiling hot desert without your hypothalamus. It accomplishes much of this work through the endocrine system and via control of the pituitary gland. The hypothalamus produces hormones, as well as factors that regulate hormone production in other parts of the brain. For example, hypothalamic neurons send axonal projections to the median eminence, an area bordering the pituitary gland. There it releases peptides (releasing factors) into the circulatory system of the

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46 | CHAPTER 2

Mammillary body

Pituitary gland

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FIGURE 2.25 Midsagittal view of the hypothalamus. Various nuclear groups are shown diagrammatically. The hypothalamus is the floor of the third ventricle, and, as the name suggests, it sits below the thalamus. Anterior is to the left in this drawing.

anterior pituitary gland. These in turn trigger (or inhibit) the release of a variety of hormones from the anterior pituitary into the bloodstream, such as growth hormone, thyroid-stimulating hormone, adrenocorticotropic hormone, and the gonadotropic hormones. Hypothalamic neurons in the anteromedial region, including the supraoptic nucleus and paraventricular nuclei, send axonal projections into the posterior pituitary gland. There they stimulate the gland to release the hormones vasopressin and oxytocin into the blood to regulate water retention in the kidneys, milk production, and uterine contractility, among other functions. Circulating peptide hormones in the bloodstream can also act on distant sites and influence a wide range of behaviors, from the fightor-flight response to maternal bonding. The hypothalamus can itself be stimulated by hormones circulating in the blood that were produced in other regions of the body.

TAKE-HOME MESSAGES ■

The thalamus is the relay station for almost all sensory information. The hypothalamus is important for the autonomic nervous system and endocrine system. It controls functions necessary for the maintenance of homeostasis. It is also involved in control of the pituitary gland. The pituitary gland releases hormones into the bloodstream where they can circulate to influence other tissues and organs (e.g., gonads).

A Guided Tour of theBrain | 47

The Telencephalon: Limbic System, Basal Ganglia, and Cerebral Cortex Toward the front of and evolutionarily newer than the diencephalon, the telencephalon develops into the cerebrum, which includes the cerebral cortex, the limbic system, and the basal ganglia. Compared to the diencephalon, the anatomy (and functions) of the forebrain above the thalamus are less straightforward. Instead of a rather linear stacking of structures, it forms a clump of structures found deep within the cerebral hemispheres nestled over and around the diencephalon. In the 17th century, Thomas Willis observed that the brainstem appeared to sport a cortical border encircling it and named it the cerebri limbus (in Latin, limbus means “border”). For better or for worse, in a move that began to tie the area with specific functioning, Paul Broca in 1878 renamed it the grand lobe limbique and suggested that it was a primary player in olfaction.

ventromedial aspect of the temporal lobe. In the 1930s James Papez (pronounced “payps”) first suggested the idea that these structures were organized into a system for emotional behavior, which led to the use of the term Papez circuit. It was named the limbic system by Paul MacLean in 1952 when he suggested the addition of more brain areas, such as the amygdala and prefrontal cortex. Note that the limbic system is neither anatomically nor functionally organized to the degree that other systems are in the brain. In fact, some researchers feel that the limbic system is sufficiently nebulous that the concept should be discarded or reevaluated. The classical limbic system, as noted earlier, has been extended to include the amygdala, a group of neurons anterior to the hippocampus, along with the orbitofrontal cortex and parts of the basal ganglia (see Figure 2.26). Sometimes the medial dorsal nucleus of the thalamus is also included. The organization and role of the limbic system are described in more detail in Chapter 10.

Basal Ganglia The basal ganglia are a collection of Limbic System The “classical” limbic lobe (Figure 2.26) is made up of the cingulate gyrus (a band of cerebral cortex that extends above the corpus callosum in the anterior–posterior direction and spans both the frontal and parietal lobes), the hypothalamus, anterior thalamic nuclei, and the hippocampus, an area located on the

nuclei bilaterally located deep in the brain beneath the anterior portion of the lateral ventricles, near the thalamus (Figure 2.27). These subcortical nuclei, the caudate nucleus, putamen, globus pallidus, subthalmic nucleus, and substantia nigra, are extensively interconnected. The caudate nucleus together with the putamen is

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FIGURE 2.26 The human limbic system. (a) Anatomy of the limbic system. (b) Major connections of the limbic system, shown diagrammatically in a medial view of the right hemisphere. The figure zooms in on the region in purple in (a). The basal ganglia are not represented in this figure, nor is the medial dorsal nucleus of the thalamus. More detail is shown here than needs to be committed to memory, but this figure provides a reference that will come in handy in later chapters.

Anterior thalamic nucleus Mammillary body

48 | CHAPTER 2

Structure and Function of the Nervous System

Level of anterior commissure Longitudinal fissure Corpus callosum Lateral ventricles

Caudate nucleus

Neostriatum Basal ganglia

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Corpus callosum Caudate nucleus

Thalamus Putamen Globus pallidus Subthalamic nucleus Mammillary bodies

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Substantia nigra Amygdala

FIGURE 2.27 Coronal and transparent views of the brain showing the basal ganglia. (a) Cross sections through the brain at two anterior–posterior levels (as indicated), showing the basal ganglia. The inset shows a transparent brain with the basal ganglia in 3D in blue. (b) Corresponding high-resolution, structural MRI (4-tesla scanner) taken at approximately the same level as the more posterior drawing in (a). This image also shows the brainstem as well as the skull and scalp, which are not shown in (a).

The Cerebral Cortex | 49 known as the striatum. The basal ganglia receive inputs from sensory and motor areas, and the striatum receives extensive feedback projections from the thalamus. A comprehensive understanding of how these deep brain nuclei function remains elusive. They are involved in a variety of crucial brain functions including action selection, action gating, motor preparation, timing, fatigue, and task switching (Cameron et al., 2009). Notably, the basal ganglia have many dopamine receptors. The dopamine signal appears to represent the error between predicted future reward and actual reward (Shultz et al., 1997), and plays a crucial role in motivation and learning. The basal ganglia may also play a big role in reward-based learning and goal-oriented behavior. One summary of basal ganglia function proposes that it combines an organism’s sensory and motor context with reward information and passes this integrated information to the motor and prefrontal cortex for a decision (Chakravarthy et al., 2009).

TAKE-HOME MESSAGES ■

The limbic system includes subcortical and cortical structures that are interconnected and play a role in emotion. The basal ganglia are involved in a variety of crucial brain functions, including action selection, action gating, reward-based learning, motor preparation, timing, task switching, and more.

The Cerebral Cortex The crowning glory of the cerebrum is its outermost tissue, the cerebral cortex. It is made up of large sheets of (mostly) layered neurons, draped and folded over the two symmetrical hemispheres like frosting on a cake. It sits over the top of the core structures that we have been discussing, including parts of the limbic system and basal ganglia, and surrounds the structures of the diencephalon. The term cortex means “bark,” as in tree bark, and in higher mammals and humans it contains many infoldings, or convolutions (Figure 2.28). The infoldings of the cortical sheet are called sulci (the crevices) and gyri (the crowns of the folded tissue that one observes when viewing the surface). The folds of the human cortex serve several functions. First, they enable more cortical surface to be packed into the skull. If the human cortex were smoothed out to resemble that of the rat, for example, humans would need to have very large heads. The total surface area of the human cerebral cortex is about 2,200 to 2,400 cm2, but because of extensive folding, about two thirds of this area is confined within the depths of the sulci. Second, having a highly folded cortex brings neurons into closer threedimensional relationships to one another, reducing axonal distance and hence neuronal conduction time between different areas. This savings occurs because the axons that make long-distance corticocortical connections run under the cortex through the white matter and do not follow the foldings of the cortical surface in their paths to

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FIGURE 2.28 The human cerebral cortex. Lateral view of the left hemisphere (a) and dorsal view of the brain (b) in humans. The major features of the cortex include the four cortical lobes and various key gyri. Gyri are separated by sulci and result from the folding of the cerebral cortex that occurs during development of the nervous system, to achieve economies of size and functionality.

50 | CHAPTER 2

Structure and Function of the Nervous System

Frontal pole

Gray matter White matter b

a Occipital pole FIGURE 2.29 Cerebral cortex and white matter tracts. (a) Horizontal section through the cerebral hemispheres at the level indicated at upper left. White matter is composed of myelinated axons, and gray matter is composed primarily of neurons. This diagram shows that the gray matter on the surface of the cerebral hemispheres forms a continuous sheet that is heavily folded. (b) High-resolution structural MRI in a similar plane of section in a living human. This T2 image was obtained on a 4-tesla scanner (a high-magnetic-field scanner). Note that on T2 images, the white matter appears darker than the gray matter, but this is due to the imaging technique, not the actual appearance.

distant cortical areas. Third, by folding, the cortex brings some nearby regions closer together; for example, the opposing layers of cortex in each gyrus are in closer linear proximity than they would be if the gyri were flattened. The cortex ranges from 1.5 to 4.5 mm in thickness, but in most regions it is approximately 3 mm thick. The cortex contains the cell bodies of neurons, their dendrites, and some of their axons. In addition, the cortex includes axons and axon terminals of neurons projecting to the cortex from other brain regions, such as the subcortical thalamus. The cortex also contains blood vessels. Because the cerebral cortex has such a high density of cell bodies, it appears grayish in relation to underlying regions that are composed primarily of the axons that connect the neurons of the cerebral cortex to other locations in the brain. These appear slightly paler or even white (Figure 2.29) because of their lipid sheaths (myelin). As described earlier, for this reason anatomists used the terms gray matter and white matter when referring to areas of cell bodies and axon tracts, respectively.

Dividing the Cortex Anatomically The cerebral hemispheres have four main divisions, or lobes, that are best seen in a lateral view: the frontal, parietal, temporal, and occipital lobes (Figure 2.30).

These names are derived from names given to the overlying skull bones; for example, the temporal lobe lies underneath the temporal bone. The skull bones themselves are named for their locations. The temporal bone lies under the temple, where the passage of time can be

Central sulcus Frontal lobe

Parietal lobe Parietooccipital sulcus

Sylvian fissure (lateral sulcus) Temporal lobe

Preoccipital notch Occipital lobe

FIGURE 2.30 The four lobes of the cerebral cortex. This is a lateral view of the left hemisphere showing the four major lobes of the brain, and some of the major landmarks that separate them.

The Cerebral Cortex | 51 observed first in the graying of hair. The word temporal derives from Latin “tempora,” meaning “time.” The lobes can usually be distinguished from one another by prominent anatomical landmarks such as pronounced sulci. The central sulcus divides the frontal lobe from the parietal lobe, and the Sylvian (lateral) fissure separates the temporal lobe from the frontal and parietal lobes. The occipital lobe is demarcated from the parietal and temporal lobes by the parieto-occipital sulcus on the brain’s dorsal surface and the preoccipital notch located on the ventrolateral surface. The left and right cerebral hemispheres are separated by the interhemispheric fissure (also called the longitudinal fissure; see Figure 2.28b) that runs from the rostral to the caudal end of the forebrain. Hidden from the lateral surface view are other parts of the cerebrum, not all of which are conveniently contained in the four lobes. For instance, the insula is located between the temporal and frontal lobe, and is, as its name implies, an island of folded cortex hidden deep in the lateral sulcus. The insula, which is surprisingly large, is divided into the larger anterior insula and smaller posterior insula. Connections between the cerebral hemispheres are via axons from cortical neurons that travel through the corpus callosum, which, as previously mentioned, represents the

largest white matter commissure in the nervous system. As we will discuss in Chapter 4, the corpus callosum carries out valuable integrative functions for the two hemispheres.

Dividing the Cortex Cytoarchitectonically The cerebral cortex can be more finely divided, both anatomically and functionally. We will take a look at both. Cytoarchitectonics uses the microanatomy of cells and their organization to subdivide the cortex (cyto– means “cell” and architectonics means “architecture”). Using histological analysis, tissue regions are defined in which the cellular architecture looks similar, and therefore might indicate areas of homogeneous function. This work began in earnest with Korbinian Brodmann at the beginning of the 20th century. Brodmann identified approximately 52 regions of the cerebral cortex. These areas were categorized and numbered according to differences in cellular morphology and organization (Figure 2.31). Other anatomists further subdivided the cortex into almost 200 cytoarchitectonically defined areas. A combination of cytoarchitectonic and functional descriptions of the cortex is probably the most effective way of dividing the cerebral cortex into 31 2 5 4

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FIGURE 2.31 Cytoarchitectonic subdivisions of the human cerebral cortex. (a) Brodmann’s original cytoarchitectonic map from his work around the start of the 20th century. Different regions of cortex have been demarcated by histological examination of the cellular microanatomy. Brodmann divided the cortex into about 52 areas. (b) Lateral view of the right hemisphere showing Brodmann’s areas color coded. Over the years, the map has been modified, and the standard version no longer includes some areas. (c) Medial view of the left hemisphere showing Brodmann’s areas. Most of Brodmann’s areas are symmetrical in the two hemispheres.

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meaningful units. In the sections that follow, we use Brodmann’s numbering system and anatomical names to describe the cerebral cortex. The Brodmann system often seems unsystematic. Indeed, the numbering has more to do with the order in which Brodmann sampled a region than with any meaningful relation between areas. Nonetheless, in some regions the numbering system roughly corresponds with the relations between areas that carry out similar functions, such as vision—e.g., Brodmann areas 17, 18, and 19. Unfortunately, the nomenclature of the cortex (and indeed the nervous system) is not fully standardized. Hence, a region might be referred to by its Brodmann name, a cytoarchitectonic name, a gross anatomical name, or a functional name. For example, let’s consider the first area in the cortex to receive visual inputs from the thalamus—the primary sensory cortex for vision. The Brodmann name is area 17 (or Brodmann area 17; i.e., BA17), another cytoarchitectonic name is striate cortex (owing to the highly visible stripe of myelin in cross sections of this cortex, known

a Layers

as the Stria of Gennari), the gross anatomical name is calcarine cortex (the cortex surrounding the calcarine fissure in humans), and the functional name is primary visual cortex, which has been labeled area V1 (for “visual area 1”) based on studies of the visual systems of monkeys. We chose primary visual cortex as an example here, because all these different terms refer to the same cortical area. Unfortunately, for much of the cortex, this is not the case; that is, different nomenclatures often do not refer to precisely the same area with a one-to-one mapping. For example, BA18 of the visual system is not fully synonymous with V2 (for “visual area 2”). Using different anatomical criteria, it is also possible to subdivide the cerebral cortex according to the general patterns of layering (Figure 2.32a, b). Ninety percent of cortex is composed of neocortex: cortex that contains six cortical layers or that passed through a developmental stage involving six cortical layers. Neocortex includes areas like primary sensory and motor cortex and association cortex (areas not obviously primary sensory or motor).

b Top

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FIGURE 2.32 Cerebral cortex, color-coded to show the regional differences in cortical layering that specify different types of cortex. (a) The lateral surface of the left hemisphere. (b) The medial surface of the right hemisphere. Neocortex is shown in red, mesocortex in blue, and allocortex in green. (c) Idealized cross section of neocortex showing a variety of cell types and the patterns of three different types of staining techniques. On the left, the Golgi preparation is apparent: Only a few neurons are stained, but each is completely visualized. In the middle, we see primarily cell bodies from the Nissl stain. On the right, we see the fiber tracks in a Weigert stain, which selectively stains myelin.

The Cerebral Cortex | 53 Mesocortex is a term for the so-called paralimbic region, which includes the cingulate gyrus, parahippocampal gyrus, insular cortex, and orbitofrontal cortex. Mesocortex is interposed between neocortex and allocortex and usually has six layers. Allocortex typically has only one to four layers of neurons and includes the hippocampal complex (sometimes referred to as archicortex) and primary olfactory cortex (sometimes referred to as paleocortex). In neocortex the cortical layers numbered 1–6 (or for the more classically minded users, I–VI) are sheets of neurons neatly stacked on top of each other. The neurons of each layer are typically similar within a layer, but different between layers. For instance, neocortical layer 4 is packed with stellate neurons, and layer 5 is predominantly pyramidal neurons (Figure 2.32c). The deeper layers, 5 and 6, mature earlier during gestation and project primarily to targets outside the cortex. Layer 4 is typically the input layer, receiving information from the thalamus as well as information from other, more distant cortical areas. Layer 5, on the other hand, is typically considered an output layer that sends information from the cortex back to the thalamus, facilitating feedback. The superficial layers mature last and primarily project to targets within the cortex. It has been suggested that the superficial layers and the connections they form within the cortex participate in the higher cognitive functions. The neurons in any one sheet, while interwoven with the other neurons in the same layer, are also lined up with the neurons in the sheets above and below it, forming columns of neurons running perpendicular to the sheets. These columns are known as minicolumns or microcolumns. These columns are not just an anatomical nicety. The neurons

within a column synapse with those from the layers above and below them, forming an elemental circuit, and appear to function as a unit. Neuronal columns are the fundamental processing unit within the cerebral cortex, and bundles of microcolumns assembled together, dubbed cortical columns, create functional units in the cortex.

Functional Divisions of theCortex The lobes of the cerebral cortex have a variety of functional roles in neural processing. Sometimes we get lucky, and the gross anatomical subdivisions of the cerebral cortex can be related fairly to specific functions, such as in the precentral gyrus where the primary motor cortex resides. More typically, however, cognitive brain systems are often composed of networks whose component parts are located in different lobes of the cortex. In addition, most functions in the brain—whether sensory, motor, or cognitive—rely on both cortical and subcortical components. Thus, it can be daunting to reveal relationships between cognitive functions and locations within the brain where they occur. The detailed functional anatomy of the brain will be revealed to you in the next twelve chapters. The rest of this section, however, provides a beginner’s guide to the functional anatomy of the cortex.

Motor Areas of the Frontal Lobe Among many other functions, the frontal lobe plays a major role in the planning and execution of movements. It has two main subdivisions: the prefrontal cortex and the motor cortex (Figure 2.33a). The motor cortex sits in front

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FIGURE 2.33 The human frontal cortex. (a) Divisions of the frontal cortex. The frontal lobe contains both motor and higher order association areas. For example, the prefrontal cortex is involved in executive functions, memory, decision making, and other processes. (b) Midsagital section of the brain showing the medial prefrontal regions, which include the anterior cingulate cortex (ACC). Also visible is the supplementary motor area.

Motor cortex

54 | CHAPTER 2

Structure and Function of the Nervous System

of the central sulcus, beginning in the depths of the sulcus and extending anteriorly. The primary motor cortex (M1) corresponds to BA4. It includes the anterior bank of the central sulcus and much of the precentral gyrus (the prefix pre- in neuroanatomy means “in front of”). Anterior to this area are two more main motor areas of cortex (within BA6; see Figure 2.31 for BA locations): the premotor cortex on the lateral surface of the hemisphere, and the supplementary motor cortex that lies dorsal to the premotor area and extends around to the hemisphere’s medial surface. These motor cortical areas contain motor neurons whose axons extend to the spinal cord and brainstem and synapse on motor neurons in the spinal cord. The output layer of primary motor cortex contains some of the most amazing neurons in the nervous system: the large pyramidal neurons known as Betz’s cells, named after Vladimir Aleksandrovich Betz, the Russian anatomist who described them in the 19th century. Betz’s cells are the largest neurons in the cerebral cortex. They reach 60 to 80 microns in diameter at the cell body, and some of them send axons several feet long down the spinal cord.

Prefrontal Cortex The more anterior regions of the frontal lobe, the prefrontal cortex, take part in the

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Thalamus in coronal section

more complex aspects of planning, organizing, and executing behavior—tasks that require the integration of information over time. Because of its facility with these tasks, the frontal lobe is often said to be the center of executive function. People with frontal lobe lesions often have difficulty reaching a goal. They may know the steps that are necessary to attain it, but they just can’t figure out how to put them together. Another problem associated with frontal lobe lesions is a lack of motivation to initiate action, to modulate it, or to stop it once it is happening. The main regions of the prefrontal cortex are the dorsolateral prefrontal cortex, the ventrolateral prefrontal cortex, the orbitofrontal cortex (Figure 2.33a), and the medial prefrontal regions, including the anterior cingulate cortex (Figure 2.33b).

Somatosensory Areas of the Parietal Lobe The parietal lobe receives sensory information from the outside world, sensory information from within the body, and information from memory, and integrates it. Parietal lobe lesions result in all sorts of odd deficits relating to sensation and spatial location: People think that parts of their body are not their own or parts of space don’t exist for them, or they may recognize objects only from certain viewpoints, or they can’t locate objects in space at all. Stimulating certain regions of the parietal lobe causes people to have “out of body” experiences (Blanke et al., 2002). Sensory information about touch, pain, temperature sense, and limb proprioception (limb position) is received via receptor cells on the skin and converted to neuronal impulses that are conducted to the spinal cord and then to the somatosensory relays of the thalamus (Figure 2.34). From the thalamus, inputs travel to the primary somatosensory cortex (or S1), a portion of the parietal lobe immediately caudal to the central sulcus (see Figure 2.33a). The next stop is the secondary somatosensory cortex (S2), which is located ventrally to S1; S2 receives most of its input from S1. Together, these cortical regions are known as the somatosensory cortex.

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FIGURE 2.34 The somatosensory cortex, which is located in the postcentral gyrus. Inputs from peripheral receptors project via the thalamus (shown in cross section) to the primary somatosensory cortex (S1). Secondary somatosensory cortex (S2) is also shown.

Topographical Mapping The specific cortical regions of the somatosensory and motor cortices that process the sensations and motor control of specific parts of the body have been mapped out. The spatial relationships of the body are fairly well preserved in the map of neural representations draped across these cortices, by using a principle known as topography (see “How the Brain Works: Cortical Topography”).

The Cerebral Cortex | 55

HOW THE BRAIN WORKS

Cortical Topography

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times called a homunculus, because it is an organized representation of the body across a given cortical area. Note that there is an indirect relation between the actual size of body parts and the cortical representation of the body’s parts. For example, areas within the motor homunculus that activate muscles in the fingers, mouth, and tongue are much larger than would be expected if the representation were proportional. The large drawings of the fingers and mouth indicate that large areas of cortex are involved in the fine coordination required when we manipulate objects or speak. Is the representation of the homunculus in the figure correct? Recent evidence from brain-imaging studies using functional magnetic resonance imaging (fMRI; described in Chapter 3) suggests that it may not be. Ravi Menon and his colleagues (Servos et al., 1999) in Canada stimulated the foreheads and chins of healthy volunteers while their brains were being scanned. In contrast to the results of the electrical-stimulation studies, the researchers found that stimulating the forehead produced activity in a region that was below (inferior to) the region for activity related to chin stimulation—the reverse of the drawing in the figure based on the work of Penfield and his colleagues. If the latter pattern from neuroimaging turns out to be accurate, it will constitute a dramatic example of scientific revisionism.

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Early insights into human cortical organization were made possible by studies that involved direct stimulation of the cortex of humans undergoing brain surgery while they were awake. Because there are no pain receptors in the central nervous system, patients experience no discomfort from stimulation. Thus, stimulation can be applied even when they are awake and fully conscious, enabling researchers to gather the patient’s subjective experiences—a relative impossibility in animal studies. Wilder Penfield and Herbert Jasper (1954) at the Montreal Neurological Institute carried out such pioneering work in the 1940s. Taking advantage of the fact that the cortex is exposed during surgery, these surgeons removed damaged brain tissue and during the same procedure, systematically explored the effects of small levels of electrical current applied to the cortical surface. In their studies, Penfield and his associates found a topographic correspondence between cortical regions and body surface with respect to somatosensory and motor processes. This correspondence is represented in Figure 1 by overlaying drawings of body parts on drawings of coronal sections of the motor and somatosensory cortex. These coronal sections are from the regions indicat ed by the color codes in the lateral view of the whole brain at the top of the figure (only one hemisphere is shown here). The resulting map of the body surface on the cortex is some-

Somatosensory Cortex

FIGURE 1 Topographic correspondence between cortical regions and body surface with respect to somatosensory and motor processes.

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For example, within the somatosensory cortex, neurons that respond to touch of the index finger are adjacent to those that respond to touch of the middle finger, which are also next to neurons that respond to touch of the ring finger. Similarly, the hand area as a whole is adjacent to the lower arm area, which is near the upper arm, and so forth. This mapping of specific parts of the body to areas of the cortex is known as somatotopy, resulting in somatotopic maps in the cortical areas. It is interesting to ask why such maps exist, since there is no inherent necessity for the organization. Yet topographic maps are a common feature of the nervous system (see Chapter 5), perhaps reflecting the fact that neighboring body parts are frequently co-recruited, as when we’re gripping a ball or stroking a favorite pet.

Visual Processing Areas in the Occipital Lobe The business of the occipital lobes is vision. The primary visual cortex is where the cerebral cortex begins to process visual information. As mentioned earlier, this area is also known as striate cortex, V1 for visual area 1, or BA17. It receives visual information relayed from the lateral geniculate nucleus of the thalamus (Figure 2.35). In humans, the primary visual cortex is on the medial surface of the cerebral hemispheres, extending only slightly onto the posterior hemispheric pole. Thus, most of the

primary visual cortex is effectively hidden from view, between the two hemispheres. The cortex in this area has six layers and begins the cortical coding of visual features like luminance, spatial frequency, orientation, and motion—features that we will take up in detail in Chapters 5 and 6. Visual information from the outside world is processed by multiple layers of cells in the retina and transmitted via the optic nerve to the lateral geniculate nucleus of the thalamus, and from there to V1—a pathway often referred to as the retinogeniculostriate, or primary visual pathway. The retina also sends projections to other subcortical brain regions by way of secondary projection systems. The superior colliculus of the midbrain is the main target of the secondary pathway and participates in visuomotor functions such as eye movements. In Chapter 7, we will review the role of the cortical and subcortical projection pathways in visual attention. Surrounding the striate cortex is a large visual cortical region called the extrastriate (“outside the striate”) visual cortex (sometimes referred to as the prestriate cortex in monkeys, to signify that it is anatomically anterior to the striate cortex). The extrastriate cortex includes BA18 and BA19 and other areas.

Auditory Processing Areas in the Temporal Lobe Medial view of left hemisphere

Striate cortex, area 17 (V1)

te

ria st a r t x Ex orte c

Ex

tr co astr rte iat x e

Lateral view of left hemisphere

Ext cor rastria tex te Calcarine fissure

Lateral geniculate nucleus of thalamus

Retina FIGURE 2.35 The visual cortex, which is located in the occipital lobe. Brodmann area 17, also called the primary visual cortex, visual area 1 (V1), and striate cortex, is located at the occipital pole and extends onto the medial surface of the hemisphere, where it is largely buried within the calcarine fissure.

The auditory cortex lies in the superior part of the temporal lobe in a region known as Heschl’s gyrus within the Sylvian fissure (Figure 2.36) and roughly corresponds with Brodmann areas 41 and 42. The auditory cortex has a tonotopic organization, meaning that the physical layout of the neurons is based on the frequency of sound. Neurons in the auditory cortex that respond best to low frequency are at one end of the cortex, and those that respond to high frequencies are at the other. The projection from the cochlea (the auditory sensory organ in the inner ear) proceeds through the subcortical relays to the medial geniculate of the thalamus and then to Heschl’s gyri, the primary auditory cortex (A1) in the supratemporal cortex. Surrounding and posterior to A1 is A2, the auditory association area. BA22, which surrounds the auditory cortex, aids in the perception of auditory inputs; when this area is stimulated, sensations of sound are produced in humans.

Association Cortex The portion of the neocortex that is neither sensory nor motor cortex has traditionally been termed the association cortex. These regions, which surround the identified sensory or motor cortical

The Cerebral Cortex | 57 Auditory cortex

a

b

FIGURE 2.36 The human auditory cortex. (a) Primary auditory cortex, which is located in the superior temporal lobe. The primary auditory cortex and surrounding association auditory areas contain representations of auditory stimuli and show a tonotopic organization. (b) This MRI shows areas of the superior temporal region in horizontal section that have been stimulated by tones of different frequencies (shown in red vs. blue) and show increased blood flow as a result of neuronal activity.

process information from the primary visual cortex about color, simple boundaries, and contours to enable people to recognize these features as a face, or a petunia, or that Maserati. Moreover, visual association cortex can be activated during mental imagery when we call up a visual memory even in the absence of visual stimulation. Or, in the case of the auditory system, the auditory association area is necessary to recognize sounds. If that area is damaged, a person can still hear sound but is unable to tell a dog’s bark from a piano concerto. As another example, the association areas of the parietal–temporal–occipital junction of the left hemisphere have a prominent role in language processing, whereas this region in the right hemisphere is implicated in attentional orienting (see Chapter 7). Thus, higher mental processes are the domain of the association cortical areas, in interaction with sensory and motor areas of cortex (Figure 2.37; “How the Brain Works: Billions and Billions”). This wraps up our whirlwind tour of the brain, but leaves us with the question of how this complicated structure—the brain—is formed in the first place. We conclude this chapter with a brief look at brain development.

TAKE-HOME MESSAGES ■

regions, contain cells that may be activated by more than one sensory modality. Association cortex receives and integrates inputs from many cortical areas; for example, inputs of the various qualities of a particular stimulus (e.g., pitch, loudness, timbre of a voice) are integrated with other sensory inputs, memory, attention, emotion, and so forth to produce our experience of the world. They are also the areas responsible for all of our highend human abilities, such as language, abstract thinking, designing such things as a Maserati, and most important, vacation planning. Each sense has a sensory association area. For example, though the primary visual cortex is necessary for normal vision, neither it nor the extrastriate cortex is the sole locus of visual perception. Regions of visual association cortex in the parietal and temporal lobes

Gyri are the protruding areas seen on the surface of the cortex; sulci, or fissures, are the enfolded regions of cortex. Brodmann divided the brain into distinct regions based on the underlying cytoarchitectonics. The lobes of the brain include the frontal, parietal, temporal, and occipital lobes. The frontal lobe is for planning, cognitive control, and execution of movements. The parietal lobe receives sensory input about touch, pain, temperature, and limb position, and it is involved in coding space and coordinating actions. The temporal lobe contains auditory, visual, and multimodal processing areas. The occipital lobe processes visual information. The limbic lobe (not really a lobe) is involved in emotional processing, learning, and memory. Topography is the principle that the anatomical organization of the body is reflected in the cortical representation of the body, both in the sensory cortex and motor cortex. Association cortices are those regions of cortex outside the sensory specific and motor cortical regions. Association cortex receives and integrates input from multiple sensory modalities.

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Motor

Gustatory

Somatosensory Primary sensory or motor cortex Secondary sensory or motor cortex Association cortex

Visual

Olfactory Auditory

FIGURE 2.37 Primary sensory and motor cortex and surrounding association cortex. The blue regions show the primary cortical receiving areas of the ascending sensory pathways and the primary output region to the spinal cord. The secondary sensory and motor areas are colored pink. The remainder is considered association cortex.

HOW THE BRAIN WORKS

Billions and Billions: Brain Size, Complexity, and Human Cognition In 2009, the big brain theory, the idea that humans were more intelligent and could credit all their high end abilities to the fact that they have a proportionately larger brain for their body than the other great apes, hit a wall. Although it had some major chinks in its armor already, for instance, the fact that Neanderthals had bigger brains than humans without possessing our scope of abilities, and that after split brain surgery the isolated left brain (with half the acreage) is just as intelligent as a whole brain, it still garnered quite a few fans. But then Suzana Herculano-Houzel (2009) and her coworkers stepped in using a new technique to more accurately count neuron numbers and found that the

human brain is a proportionately scaled-up primate brain, no bigger than what you would expect for an ape of our size. It turns out that the human brain has on average 86 billion neurons, with 69 billion of them located in the cerebellum. The entire cortex, the area that we think is responsible for human thought and culture, has only 17 billion (19% of all the neutrons in the brain and similar to the percent found in other mammals), leaving only one billion for the entire rest of the brain. Not only that, but the visual and other sensory areas and the motor cortex have way more neurons than the frontal lobes (including the prefrontal cortex—that part of the human brain that is involved with all the high

The Cerebral Cortex | 59

end abilities such as memory and planning, cognitive flexibility, abstract thinking, initiating appropriate behavior and inhibiting inappropriate behavior, learning rules, and picking out relevant information perceived through the senses). So what accounts for increased abilities? Interestingly, the volume of the human cerebral cortex is 2.75 times larger than in chimpanzees, but has only 1.25 times more neurons (Shariff, 1953). One thing that neuroanatomists have discovered is that the dendritic tips of the front lobe neurons are more arborized: They are chock full of branches with the resulting possibility of increased neuronal connections. This suggests that it may be the connectivity patterns of the neurons themselves that is different.

Generally in the brain, the larger an area is, the better connected it is with more neurons, and more neurons connected to each other, but there is a limit. If our brains were fully connected, each neuron connected to every other one, our brains would have to be 20 kilometers in diameter (Clark & Sokoloff, 1999) and would require so much energy that all our time (and then some) would be spent eating. Big heads, indeed! With such distances for axons to travel across the brain, the processing speed would be slowed down, no doubt creating an uncoordinated body and rather dull witted person. So, as the primate brain evolved and the number of neurons increased, not every neuron connected to every other neuron. This resulted in an actual fall in the percent of connectedness. It appears that certain wiring “laws” apply to the evolutionary development of the large human brain (Striedter, 2005). ■

FIGURE 1 Variability of brain size and external topography.

Decreased long distance brain connectivity with increasing size. The number of neurons that an average neuron connects to actually does not change with increasing brain size. By maintaining absolute connectivity, not proportional connectivity, large brains became less interconnected. No need to worry about this, because evolution came up with two clever solutions. Minimizing connection lengths. Short connections keep processing localized, with the result that less space is needed fro the shorter axons, less energy is required, and signaling is faster over shorter distances. This organization set the stages for local networks to divide up and specialize, forming multiple clusters of processing modules. Not all connections are minimized, but some very long connections between distant sites are retained. Primate brains in general, and human brains in particular, have developed what is known as “small-world architecture,” which is common to many complex systems, including human social relations. This type of organizational structure combines many short fast local connections with a few long distance ones to communicate the results of the local processing. It also has the advantage that a smaller number of steps connect any two processing units. This design allows both a high degree of local efficiency and at the same time, quick communication to the global network.

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Development of the Nervous System Thus far, we have been discussing the neuroanatomy of the developed adult brain. In humans and many other species, the fetal brain is well developed and shows cortical layers, neuronal connectivity, and myelination; in short, it is already extremely complex, although by no means completely developed. To find out how this complex brain develops prenatally and to uncover the rules governing development, let’s examine the development of the nervous system and give special attention to the neocortex.

Overview of Gross Development From a single fertilized egg, an organism made up of billions of cells with specialized functions will arise. This

Neural ectoderm

Mesoderm

complexity clearly peaks in the nervous system. Fertilization is followed by a series of events leading to the formation of a multicellular blastula, which has already begun to specialize. The blastula contains three main cell lines, which after a few days form three layers: the ectoderm (outer layer) that will form the nervous system and the outer skin, lens of the eye, inner ear, and hair; the mesoderm (middle layer) that forms the skeletal system and voluntary muscle; and the endoderm (inner layer) that will form the gut and digestive organs. The early processes that go into forming the nervous system are called neurulation (Figure 2.38). During this stage, the ectodermal cells on the dorsal surface form the neural plate. As the nervous system continues to develop, the cells at the lateral borders of the neural plate push upward. (Imagine joining the long sides of a rectangular piece of dough to form a tube.) This movement causes the more central cells of the neural plate to invaginate, or dip inward, to form the neural groove. As the groove deepens, the cells pushing up at the border of the neural fold region eventually meet and fuse, forming the neural tube that runs anteriorly and posteriorly along the embryo. The adjacent nonneural ectoderm then reunites to seal the neural tube within an ectodermal covering that surrounds the embryo.

Endoderm Ectoderm Neural plate

Notochord

Notochord

Neural plate

Neural groove

Somite (mesoderm)

Gut

Ectoderm

Mesoderm

Central canal

28 day embryo FIGURE 2.38 Development of the vertebrate nervous system. Cross sections through the blastula and embryo at various developmental stages during the first 21 days of life. Early in embryogenesis, the multicellular blastula (top) contains cells destined to form various body tissues. Migration and specialization of different cell lines leads to formation of the primitive nervous system around the neural groove and neural tube on the dorsal surface of the embryo. The brain is located at the anterior end of the embryo and is not shown in these more posterior sections, which are taken at the level of the spinal cord.

Development of the Nervous System | 61

HOW THE BRAIN WORKS

Blood Supply and the Brain Approximately 20% of the blood flowing from the heart is pumped to the brain. A constant flow of blood is necessary, because the brain has no way of storing glucose or extracting energy without oxygen. When the flow of oxygenated blood to the brain is disrupted for only a few minutes, unconsciousness and death can result. Two sets of arteries bring blood to the brain: the vertebral arteries, which supply blood to the caudal portion of the brain, and the internal carotid arteries, which supply blood to wider brain regions (Figure 1). Although the major arteries sometimes join together and then separate again, little mixing of blood occurs between the rostral and caudal arterial supplies or between the right and left sides of the rostral portion of the brain. As a safety measure, in the event of a blockage or ischemic attack, blood should be rerouted to reduce the probability of loss of blood supply; but in practice, this rerouting of the blood supply is relatively poor. Blood flow in the brain is tightly coupled with metabolic demand of the local neurons. Hence, increases in neuronal activity lead to a coupled increase in regional cerebral blood flow. Increased blood flow is not primarily for increasing the delivery of oxygen and glucose to the active tissue, but rather to hasten removal of the resultant metabolic by-products of the increased neuronal activity. The precise mechanisms for altering blood flow, however, remain hotly debated. These local changes in blood flow permit regional cerebral blood flow to be used as a measure of local changes in neuronal activity, and serve as the basis for some types of functional neuroimaging. Particular examples are positron emission tomography, using techniques such as the 15O-water method, and functional magnetic resonance imaging, which is sensitive to changes in the concentration of oxygenated versus deoxygenated blood in the region of active tissue.

Middle cerebral artery Cortical branches of anterior cerebral artery

Cortical branches of middle cerebral artery in lateral sulcus

Posterior cerebral artery

Segments of internal carotid artery: Carotid syphon Intrapetrosal Cervical

Branches of anterior cerebral artery:

Branches of posterior cerebral artery:

Callosomarginal

Parietooccipital

Pericallosal Calcarine

Frontopolar and medial orbitofrontal Anterior cerebral artery Internal carotid artery Basilar artery Vertebral artery

Circle of Willis Middle cerebral artery: Superficial (cortical) branches Deep (lenticulostriate) branches Anterior choroidal artery Basilar artery Anterior inferior cerebellar artery Posterior inferior cerebellar artery

FIGURE 1 Blood supply and the brain.

Superior cerebellar artery Posterior inferior cerebellar artery

Anterior cerebral artery Internal carotid artery Middle cerebral artery Posterior cerebral artery Superior cerebellar artery Vertebral artery Anterior spinal artery

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Structure and Function of the Nervous System

Hindbrain

Midbrain

Cephalic flexure

Pons and cerebellum

Pontine flexure

after birth (but see the section called “Birth of New Neurons Throughout Life,” later in this chapter). Although axonal myelination continues for some period postnatally (e.g., until adulthood in the human frontal lobe), the newborn has a well-developed cortex that includes the cortical layers and areas characterized in adults. For instance, BA17 (the primary visual cortex) can be distinguished from the motor cortex by cytoarchitectonic analysis of its neuronal makeup.

Midbrain Cervical flexure

Neural Proliferation and Migration of Cortical Cells The neu-

rons that form the brain arise from a layer of precursor cells in prolifMedulla erative zones located adjacent to the Diencephalon ventricles of the developing brain. Spinal The cortical neurons arise from the Cerebral cord cortex subventricular zone, and those that a b form other parts of the brain arise from precursor cells in the ventricuFIGURE 2.39 Early stages of embryonic development in mammals. lar zone. For this discussion, refer to (a) Developing embryo. The embryo goes through a series of folds, or flexures, during developFigure 2.40, which shows a cross ment. These alterations in the gross structure of the nervous system give rise to the comsection through the cortex and the pact organization of the adult brain and brainstem in which the cerebral cortex overlays the precursor cell layers at various times diencephalon and midbrain within the human skull. (b) There is significant similarity between the gross features of the developing fetuses of mammals, as shown by this comparison of a during gestation. We will now conhuman fetus (top) and pig fetus (bottom). centrate on the cells that form the cortex. The precursor cells are undifferentiated cells from which all cortical cells, including At both ends of the neural tube are openings (the neuronal subtypes and glial cells, arise through cell divianterior and the posterior neuropores) that close on about sion and differentiation. For the first five to six weeks of the 23rd to 26th day of gestation. When the anterior gestation, the cells in the subventricular zone divide in a neuropore is sealed, this cavity forms the primitive brain, symmetrical fashion. The result is exponential growth in consisting of three spaces, or ventricles. If the neuropores the number of precursor cells. do not close correctly, neural tube defects such as At the end of six weeks, when there is a stockpile anencephaly (absence of a major portion of the brain of precursor cells, asymmetrical division begins. After and skull) or spina bifida (some of the vertebrae are not every cell division, one of the two cells formed becomes formed) may result. From this stage on, the brain’s gross a migratory cell destined to be part of another layer; the features are formed by growth and flexion (bending) of other cell remains in the subventricular zone, where it the neural tube’s anterior portions (Figure 2.39). The continues to divide asymmetrically. Later in gestation, result is a cerebral cortex that envelops the subcortical the proportion of migratory cells increases until a lamiand brainstem structures. The final three-dimensional nar (i.e., layered) cortex made up of the migratory cells relations of the brain’s structures are the product of is formed. This cortex has a foundational epithelial layer continued cortical enlargement and folding. The posterior that becomes the cell lining of the ventricles and is known portion of the neural tube differentiates into a series of as the ependymal cell layer. repeated segments that form the spinal cord. The migratory cells travel outward from the subvenIn primates, almost all neurons are generated prenatricular zone by moving along peculiar cells known as tally during the middle third of gestation. The entire adult radial glial cells, which stretch from the subventricular pattern of gross and cellular neural anatomical features is zone to the surface of the developing cortex. The work present at birth, and there is little generation of neurons

Development of the Nervous System | 63 of radial glial cells does not end with development. These cells are transformed into astrocytes in the adult brain, helping to form part of the blood–brain barrier. As the first migrating neurons approach the surface of the developing cortex—a point known as the cortical plate— they stop short of the surface. Neurons that migrate later pass beyond the termination point of the initial neurons and end up in more superficial positions—positions nearer the outer cortical surface. Thus, it is said that the cortex is built from the inside out, because the first neurons to migrate lie in the deepest cortical layers, whereas the last to migrate move farthest out toward the cortical surface.

The timeline of cortical neurogenesis differs across cortical cytoarchitectonic areas, but the inside-out pattern is the same for all cortical areas. Because the timeline of cortical neurogenesis determines the ultimate pattern of cortical lamination, anything that affects the genesis of cortical neurons will lead to an ill-constructed cortex. A good example of how neuronal migration can be disrupted in humans is fetal alcohol syndrome. In cases of chronic maternal alcohol abuse, neuronal migration is severely disrupted and results in a disordered cortex, leading to a plethora of cognitive, emotional, and physical disabilities.

The Radial Unit Hypothesis We now have a picture Neuronal Determination and Differentiation The cortex is made up of many different types of neurons organized in a laminar fashion. Layer IV, for example, contains large pyramidal cells, layer III is populated primarily by stellate cells, and so on. You may be wondering how that population of virtually identical precursor cells gives rise to the variety of neurons and glial cells in the adult cortex. What determines the type of neuron that a migrating cell is fated to become? The answer lies in the timing of neurogenesis. Experimental manipulation of developing cells has shown that the differentiated cell type is not hardwired into the code of each developing neuron. Neurons that are experimentally prevented from migrating, by exposing them to high-energy X-rays, eventually form cell types and patterns of connectivity that would be expected from neurons that were created at the same gestational stage. Even though the thwarted neurons might remain in the ventricular zone, they display interconnections with other neurons that would be normal had they migrated to the cortical layers normally.

MZ

MZ CP

MZ

IZ

IZ

VZ

VZ

VZ

of how cortical neurons are born and how they migrate radially from the ventricular zone toward the surface of the developing cortex. The neurons migrate along the radial glial cells that form a pathway for them. Because the radial glial highway is organized in a straight line from the ventricular zone to the cortical surface, there is a topographic relation between the precursor and proliferating neurons in the ventricular area and the cortical neurons that they yield in the adult. Hence, cells born next to each other in the ventricular zone end up near each other (in the plane perpendicular to the surface of cortex) in the cortex. In addition, cells derived from precursor cells distant from one another will ultimately be distant in the cortex. Cortical surface

ML MZ CP

Cortical layers

CO

MZ

SP

IZ

IZ

SZ

SZ

SZ

VZ

VZ

EL

Time during histogenesis of cortex FIGURE 2.40 Histogenesis of the cerebral cortex. Cross-sectional views of developing cerebral cortex at early (left) and late (right) times during histogenesis. The mammalian cortex develops from the inside out as cells in the ventricular zone (VZ) divide, and some of the cells migrate to the appropriate layer in the cortex. Radial glial cells form a superhighway along which the migrating cells travel en route to the cortex. CO = cortex; CP = cortical plate; EL= ependymal layer; IZ = intermediate zone; ML = molecular layer; MZ = marginal zone; SP = subplate; SZ= subventricular zone; WM = white matter.

WM

White matter

Ependymal layer

64 | CHAPTER 2

Structure and Function of the Nervous System 100 90

77

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47 39 31 2 11 1

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Marginal zone E100 Cortical plate E40 E38–E48

Subplate Radial glial cells

Corticocortical inputs

Migrating neurons

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Thalamic inputs

77 65

55 47 39 31

Ventricular zone 2

11

1

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3

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5 6 7

8 9 10

FIGURE 2.41 Radial unit hypothesis. Radial glial cells in the ventricular zone project their processes in an orderly map through the various cortical layers, thus maintaining the organizational structure specified in the ventricular layer. (E = Embryonic day.)

According to this concept, termed the radial unit hypothesis by neuroscientist Pasko Rakic (1995) of Yale University, the columnar organization in the adult cortex is derived during development from cells that divide in the ventricular region (Figure 2.41). The cortical column is thus a principal unit of organization that has functional consequences and a developmental history. The radial unit hypothesis also provides a method for the evolutionary expansion of cortical size: Each unit is not enlarged; instead, the number of units increases. The radial unit and the cortical columns that arise from these groupings have functional and anatomical consequences in the adult. For example, the intracortical interconnectivity of local neurons appears to be well suited to the sizes of cortical columns, which vary in adults from about

100 μm to 1 μm on a side, depending on the species and cortical area.

Birth of New Neurons Throughout Life One principle about the human brain that, until recently, dominated in the neuroscience community, is the idea that the adult brain produces no new neurons (Figure 2.42). This view has been held despite a variety of claims of neurogenesis in the brain in histological studies dating as far back as the time of Ramón y Cajal. Recent studies using an array of modern neuroanatomical techniques have challenged this belief.

Development of the Nervous System | 65

FIGURE 2.42 This cartoon exposes the commonly held belief that once we lose neurons, they can never be replaced. © Bryan Reading/www.cartoonstock.com.

Neurogenesis in adult mammals has now been well established in two brain regions: the hippocampus and the olfactory bulb. Neurogenesis in the hippocampus is particularly noteworthy because it plays a key role in learning and memory (see Chapter 9). In rodents, studies have shown that stem cells in a region of the hippocampus known as the dentate gyrus produce new neurons in the adult, and these can migrate into regions of the hippocampus where similar neurons are already functioning. It is important to know that these new neurons can form dendrites and send out

axons along pathways expected of neurons in this region of the hippocampus, and they can also show signs of normal synaptic activity. These findings are particularly interesting because the number of new neurons correlates positively with learning or enriched experience (more social contact or challenges in the physical environment) and negatively with stress (e.g., living in an overcrowded environment). Moreover, the number of newborn neurons is related to hippocampal-dependent memory (Shors, 2004). Other investigators have found that these new neurons become integrated into functional networks of neurons and participate in behavioral and cognitive functions in the same way that those generated during development do (Ramirez-Amaya et al., 2006). Future work will be required to establish whether adult neurogenesis occurs more broadly in the mammalian brain or is restricted to the olfactory bulb and hippocampus. What about the adult human brain? Does neurogenesis also occur in mature humans? In a fascinating line of research, a team of scientists from California and Sweden (Eriksson et al., 1998) explored this question in a group of terminally ill cancer patients. As part of a diagnostic procedure related to their treatment, the patients were given BrdU, a synthetic form of thymidine used as a label to identify neurogenesis. The purpose was to assess the extent to which the tumors in the cancer patients were proliferating; tumor cells that were dividing would also take up BrdU, and this label could be used to quantify the progress of the disease.

FIGURE 2.43 Newly born neurons in adult human. (a) The hippocampus of the adult human brain, stained for a neuronal marker (NeuN). (b) The dentate gyrus granule cell layer (GCL) in a NeuN-stained section. (c) Bromodeoxyuridine (BrdU)-labeled nuclei (arrows) in the granule cell layer of the dentate gyrus. (d) BrdU-labeled cells (arrow) in the granule cell layer of the dentate gyrus. (e) BrdU-stained cells (arrows) adjacent to the ependymal lining in the subventricular zone (SZ) of the human caudate nucleus. These neurons have elongated nuclei resembling the migrating cells that typically are found in the rat subventricular zone. (f) BrdU-stained cells (arrows) with round to elongated nuclei in the subventricular zone of the human caudate nucleus. The horizontal black bars are scale bars representing 50 μm.

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FIGURE 2.44 The birth of new neurons in the dentate gyrus of the adult human (a–h) compared to those in the adult rat (i–l). New neurons show simultaneous labeling for different stains. (a) A neuron is labeled for NeuN, a neuronal marker. (b) The same cell is labeled with BrdU, indicating that it is newly born (full arrow). (Note that the lone arrowheads in (a) through (d) are pointing to neurons that are fluorescing red or green, owing to nonspecific staining; i.e., these are not newly born neurons). (c) This same cell is not stained by glial fibrillary acidic protein (GFAP), indicating that it is not an astrocyte. (d) The three stained sections are merged. The image shows that a BrdU-labeled cell could specifically coexpress NeuN without expressing GFAP. Confocal microscopy permits examination of the coexpression of NeuN and BrdU in the neuron by focusing the image above (e, f) and below (g, h) the level of the section shown in panel (d). Note that red blood cells and endothelial cells, present in several small blood vessels, show nonspecific staining, as indicated by the asterisks in (e) through (h). Panels (i) through (l) show the similarity of the BrdU-labeled neurons in rat dentate gyrus. Note: The scale bar in (a) is 25 μm, and the scale is the same for panels (a) through (h). The scale bar in panel (i) is also 25 μm and is the scale for (i) through (l), but the magnification for (i) through (l) is higher than for (a) through (h).

Neurons undergoing mitotic division during neurogenesis in these patients also took up the BrdU, which could be observed in postmortem histological examinations of their brains. The postmortem tissue was immunostained to identify neuron-specific cell surface markers. The scientists found cells labeled with BrdU in the subventricular zone of the caudate nucleus and in the granular cell layer of the dentate gyrus of the hippocampus (Figure 2.43). By staining the tissue to identify neuronal markers, the researchers showed that the BrdU-labeled cells were neurons (Figure 2.44). These findings demonstrate that new neurons are produced in the adult human brain, and that our brains renew themselves throughout life to an extent not previously thought possible.

These exciting results hold great promise for the future of neuroscience. Research is under way to investigate the functionality of new neurons in the adult brain and to determine whether or not such neuronal growth can be facilitated in order to ameliorate brain damage or the effects of diseases such as Alzheimer’s.

The Baby Brain: Ready to Rock ’n’ Roll? A host of behavioral changes takes place during the first months and years of life. What accompanying neurobiological changes enable these developments? Even if we

Development of the Nervous System | 67 assume that neuronal proliferation continues, we know that at birth the human brain has a fairly full complement of neurons, and these are organized to form a human nervous system that is normal, even if not complete in all details. What details are incomplete, and what is known about the time course of the maturation of the brain? Although the brain nearly quadruples in size from birth to adulthood, it is not because of an increase in neuron number. A substantial amount of that growth comes from synaptogenesis (the formation of synapses) and the growth of dendritic trees. Synapses in the brain begin to form long before birth—prior to week 27 in humans (counting from conception)—but they do not reach peak density until after birth, during the first 15 months of life. Synaptogenesis is more pronounced early in the deeper cortical layers and occurs later in more superficial layers, following the pattern of neurogenesis described earlier. At roughly the same time that synaptogenesis is occurring, neurons of the brain are increasing the size of their dendritic arborizations, extending their axons, and undergoing myelination. Synaptogenesis is followed by synapse elimination (sometimes called pruning), which continues for more than a decade. Synapse elimination is a means by which the nervous system fine-tunes neural connectivity, presumably eliminating the interconnections between neurons that are redundant, unused, or do not remain functional. An example comes from primary visual cortex (BA17): Initially, there is overlap between the projections of the two eyes onto neurons in BA17. After synapse elimination, the cortical inputs from the two eyes within BA17 are nearly completely segregated. The axon terminals relaying information from each eye form a series of equally spaced patches (called ocular dominance columns), and each patch receives inputs from predominantly one eye. One of the central hypotheses about the process of human synaptogenesis and synapse elimination is that the time course of these events differs in different cortical regions. The data suggest that in humans, synaptogenesis and synapse elimination peak earlier in sensory (and motor) cortex than in association cortex. By contrast, in the brain development of other primates, synaptogenesis and pruning appear to occur at the same rates across different

cortical regions. Differences in methodology, however, must be resolved before these interspecies variations will be wholly accepted. Nonetheless, compelling evidence suggests that different regions of the human brain reach maturity at different times. The increase in brain volume that occurs postnatally is also a result of both myelination and the proliferation of glial cells. White matter volume increases linearly with age across cortical regions (Giedd et al., 1999). In contrast, gray matter volume increases nonlinearly, showing a preadolescent increase followed by a postadolescent decrease. In addition, the time course of gray matter increase and decrease are not the same across different cortical regions. In general, these data support the idea that postnatal developmental changes in the human cerebral cortex may not occur with the same time course across all cortical regions (see also Shaw et al., 2006).

TAKE-HOME MESSAGES ■

The nervous system develops from the ectoderm, which forms a neural plate. The neural plate becomes the neural groove and eventually the neural tube. Neuronal proliferation is the process of cell division in the developing embryo and fetus. It is responsible for populating the nervous system with neurons. Neurons and glial cells are formed from precursor cells. After mitosis, these cells migrate along the radial glial cells to the developing cortex. The type of cell that is made (e.g., a stellate or pyramidal cell) appears to be based on when the cell is born (genesis) rather than when it begins to migrate. The radial unit hypothesis states that the columnar organization in the adult cortex is derived during development from cells that divide in the ventricular region. A belief strongly held by most neuroscientists was that the adult brain produces no new neurons. We now know that this is not the case; new neurons form throughout life in certain brain regions. Synaptogenesis is the birth of new synapses; neurogenesis is the birth of new neurons.

Summary In terms of evolution, the oldest parts of the brain, which make up the brain stem structures, control our most basic survival functions, such as breathing, heart rate, and temperature. The more rostral structures evolved more recently and mediate more complex behaviors. The most rostral and youngest structure is the prefrontal cortex and is found only in mammals. In the brain and the rest of the nervous system, nerve cells (neurons) provide the mechanism for information processing. Neurons can receive and process sensory inputs, plan and organize motor acts, and enable human thought. At rest, the neuronal membrane has properties that allow some materials (primarily ions) dissolved in intracellular and extracellular fluids to pass through more easily than others. In addition, active transport processes pump ions across the membrane to separate different species of ions, thereby setting the stage for differences in electrical potential inside and outside the neuron. These electrical differences are a form of energy that can be used to generate electrical currents that, via action potentials, can travel great distances down axons away from the neuron’s cell body. When the action potential reaches an axon terminal, it prompts the release of chemicals at a specialized region, the synapse, where the neuron contacts another neuron, muscle, or gland. These chemicals (neurotransmitters) diffuse across the synaptic cleft between the neurons and contact receptor molecules in the next (postsynaptic) neuron. This chemical

transmission of signal leads to the generation of currents in the postsynaptic neuron and the continuation of the signal through the system of neurons that make up a neuronal circuit. Ion channels are the specialized mediators of neuronal membrane potential. They are large transmembrane proteins that create pores through the membrane. Transmembrane proteins also form receptors on postsynaptic neurons. These are the receptors that bind with neurotransmitters, leading to changes in the membrane potential. Neurotransmitters come in a large variety of forms. Small-molecule transmitters include amino acids, biogenic amines, and substances like ACh; large-molecule transmitters are the neuropeptides. Neuronal circuits are organized to form highly specific interconnections between groups of neurons in subdivisions of the central nervous system. The functions might be localized within discrete regions that contain a few or many subdivisions, identifiable either anatomically or functionally, but usually by a combination of both approaches. Brain areas are also interconnected to form higher level circuits or systems that are involved in complex behaviors such as motor control, visual perception, or cognitive processes such as memory, language, and attention. Neurodevelopment begins at an early stage in fetal growth and continues through birth and adolescence. New research also suggests that new neurons and new synapses form throughout life, allowing, at least in part, for cortical plasticity.

Key Terms action potential (p. 30) amygdala (p. 47) association cortex (p. 56) autonomic nervous system (p. 38) axon (p. 26) axon collateral (p. 26) axon hillock (p. 30) basal ganglia (p. 47) blood–brain barrier (BBB) (p. 36) brainstem (p. 43) central nervous system (CNS) (p. 37) central sulcus (p. 51) cerebellum (p. 44) cerebral cortex (p. 38) commissure (p. 39) corpus callosum (p. 39) cytoarchitectonics (p. 51) dendrite (p. 25) depolarize (p. 31) 68

dura mater (p. 38) electrical gradient (p. 29) electrotonic conduction (p. 30) equilibrium potential (p. 31) frontal lobe (p. 50) glial cell (p. 35) gray matter (p. 39) gyrus (p. 49) hippocampus (p. 47) hyperpolarization (p. 31) hypothalamus (p. 45) insula (p. 51) ion channel (p. 28) ion pump (p. 28) layer (p. 38) limbic system (p. 47) medulla (p. 43) midbrain (p. 44) myelin (p. 26)

neocortex (p. 52) neural circuit (p. 37) neural system (p. 37) neuron (p. 24) neurotransmitter (p. 33) node of Ranvier (p. 26) nucleus (p. 38) occipital lobe (p. 50) parietal lobe (p. 50) peripheral nervous system (PNS) (p. 37) permeability (p. 29) pituitary gland (p. 46) pons (p. 44) postsynaptic (p. 27) prefrontal cortex (p. 54) presynaptic (p. 27) refractory period (p. 31) resting membrane potential (p. 27)

saltatory conduction (p. 32) soma (p. 25) somatotopy (p. 56) spike-triggering zone (p. 30) spine (p. 26) sulcus (p. 49) Sylvian (lateral) fissure (p. 51)

synapse (p. 26) synapse elimination (p. 67) synaptic cleft (p. 32) synaptogenesis (p. 67) temporal lobe (p. 50) thalamus (p. 45) threshold (p. 31)

topography (p. 54) tract (p. 39) vesicle (p. 32) voltage-gated ion channel (p. 30) white matter (p. 39)

Thought Questions 1. 2.

If action potentials are all or none, how does the nervous system code differences in sensory stimulus amplitudes? What property (or properties) of ion channels makes them selective to only one ion, such as K+, and not another, such as Na+? Is it the size of the channel, other factors, or a combination?

3.

Given that synaptic currents produce electrotonic potentials that are decremental, how do inputs located distantly on a neuron’s dendrites have any influence on the firing of the cell?

4.

What would be the consequence for the activity of a postsynaptic neuron if reuptake or degradation systems for neurotransmitters were damaged?

5. 6.

What are glial cells and what are their functions?

7.

Why are almost all sensory inputs routed through the thalamus on the way to cortex? Wouldn’t it be faster and therefore more efficient to project these inputs directly from sensory receptors to the primary sensory cortex?

8.

What brain areas have been associated with the creation of new neurons and what functions are they thought to perform?

What region of the cerebral cortex has increased in size the most across species during evolution? What function does this brain region carry out in humans that is absent or reduced in animals?

Suggested Reading Aimone, J. B., Deng, W., & Gage, F. H. (2010). Adult neurogenesis: Integrating theories and separating functions. Trends in Cognitive Sciences, 14(7), 325–337. Epub 2010 May 12. Bullock, T. H., Bennett, M. V., Johnston, D., Josephson, R., Marder, E., & Fields, R. D. (2005). The neuron doctrine, redux. Science 310, 791. doi:10.1126/science .1114394

syndromes, the limbic system, and hemispheric specialization. In Shaw, P., Greenstein, D., Lerch, J., Clasen, L., Lenroot, R., Gogtay, N., et al. (2006). Intellectual ability and cortical development in children and adolescents. Nature, 440, 676–679. Shepherd, G. M. (1988). Neurobiology (2nd ed.). New York: Oxford University Press.

Haeusser, M. (2000). The Hodgkin–Huxley theory of the action potential. Nature Reviews Neuroscience, 3, 1165.

Shors, T. J. (2004). Memory traces of trace memories: Neurogenesis, synaptogenesis and awareness. Trends in Neurosciences, 27, 250–256.

Mesulam, M.-M. (2000). Behavioral neuroanatomy: Large-scale networks, association cortex, frontal

Streidter, G. (2005). Principles of brain evolution, pps. 217–53. Sunderland, MA: Sinawer.

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Though this be madness, yet there is method in’t. William Shakespeare

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3 chapter

IN THE YEAR 2010, Halobacterium halobium and Chlamydomonas reinhardtii made it to prime time as integral parts of the journal Nature’s “Method of the Year.” These microscopic creatures were hailed for their potential to treat a wide range of neurological and psychiatric conditions: anxiety disorder, depression, OUTLINE and Parkinson’s disease, just to name a few. Not bad for a bacterium that hangs out in warm brackish waters and an alga more commonly known as Cognitive Psychology and pond scum. Behavioral Methods Such grand ambitions for these humble creatures likely never occurred to Studying the Damaged Brain Dieter Oesterhelt and Walther Stoeckenius (1971), biochemists who wanted to understand why the salt-loving Halobacterium, when removed from its salty Methods to Perturb Neural Function environment, would break up into fragments, and why one of these fragments Structural Analysis of the Brain took on an unusual purple hue. Their investigations revealed that the purple color was due to the interaction of retinal (a form of vitamin A) and a protein Methods for the Study of produced by a set of “opsin genes.” Thus they dubbed this new compound Neural Function bacteriorhodopsin. The particular combination surprised them. Previously, The Marriage of Function and the only other place where the combined form of retinal and an opsin proStructure: Neuroimaging tein had been observed was in the mammalian eye, where it serves as the Brain Graphs chemical basis for vision. In Halobacterium, bacteriorhodopsin functions as an ion pump, converting light energy into metabolic energy as it transfers ions Computer Modeling across the cell membrane. Other members of this protein family were identiConverging Methods fied over the next 25 years, including channelrhodopsin from the green algae C. reinhardtii (Nagel et al., 2002). The light-sensitive properties of microbial rhodopsins turned out to provide just the mechanism that neuroscientists had been dreaming of. In 1979, Francis Crick, a codiscoverer of the structure of DNA, made a wish list for neuroscientists. What neuroscientists really need, he suggested, was a way to selectively switch on and off neurons, and to do so with great temporal precision. Assuming this manipulation did not harm the cell, a technique like this would enable researchers to directly probe how neurons functionally relate to each other in order to control behavior. Twenty years later, Crick (1999) proposed that light might somehow serve as the switch, because it could be precisely delivered in timed pulses. Unknown to him, and the neuroscience community in general, the key to 71

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developing this switch was moldering away in the back editions of plant biology journals, in the papers inspired by Oesterhelt and Stoeckenius’s work on the microbial rhodopsins. A few years later, Gero Miesenböck provided the first demonstration of how photoreceptor proteins could control neuroactivity. The key challenge was getting the proteins into the cell. Miesenböck accomplished this feat by inserting genes that, when expressed, made targeted cells light responsive (Zemmelman et al., 2002). Expose the cell to light, and the neuron would fire. With this methodological breakthrough, optogenetics was born (Figure 3.1). Miesenböck’s initial compound proved to have limited usefulness, however. But just a few years later, two graduate students at Stanford, Karl Deisseroth and Ed Boyden, became interested in the opsins as possible neuronal switches (Boyden, 2011). They focused on channelrhodopsin-2 (ChR-2), since a single gene encodes this opsin, making it easier to use molecular biology tools. Using Miesenböck’s technique, a method that has come to be called viral transduction, they spliced the

gene for ChR-2 into a neutral virus and then added this virus to a culture of live nerve cells growing in a petri dish. The virus acted like a ferry, carrying the gene into the cell. Once the ChR-2 gene was inside the neurons and the protein had been expressed, Deisseroth and Boyden performed the critical test: They projected a light beam onto the cells. Immediately, the targeted cells began to respond. By pulsing the light, the researchers were able to do exactly what Crick had proposed: precisely control the neuronal activity. Each pulse of light stimulated the production of an action potential; and when the pulse was discontinued, the neuron shut down. Emboldened by this early success, Deisseroth and Boyden set out to see if the process could be repeated in live animals, starting with a mouse model. Transduction methods were widely used in molecular biology, but it was important to verify that ChR-2 would be expressed in targeted tissue and that the introduction of this rhodopsin would not damage the cells. Another challenge these scientists faced was the need to devise a method of delivering light pulses to the transduced cells. For their

a

c Off

b

FIGURE 3.1 Optogenetic control of neural activity. (a) Hippocampal neuron that has been genetically modified to express Channelrhododopsin-2, a protein which forms light-gated ion channels. (b) Activity in three neurons when exposed to a blue light. The small grey dashes below each neuron indicate when the light was turned on (same stimulus for all three neurons). The firing pattern of the cells is tightly coupled to the light, indicating the experimenter can control, to a large extent, the activity of the cells. (c) Behavioral changes resulting from optogenetic stimulation of cells in a subregion of the amygdala. When placed in an open, rectangular arena, mice generally stay close to the walls. With amygdala activation, the mice become less fearful, venturing out into the open part of the arena.

On

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THE SCIENTIFIC METHOD The overarching method that neuroscientists use, of course, is the scientific method. This process begins with an observation of a phenomenon. Such an observation can come from various types of populations: animal or human, normally functioning or abnormally functioning. The scientist devises a hypothesis to explain an observation and makes predictions drawn from the hypothesis. The next step is designing experiments to test the hypothesis and its predictions.

initial in vivo study, they implanted a tiny optical fiber in the part of the brain containing motor neurons that control the mouse’s whiskers. When a blue light was pulsed, the whiskers moved (Aravanis et al., 2007). Archimedes, as well as Frances Crick, would have shouted, “Eureka!” Optogenetic techniques are becoming increasingly versatile (for a video on optogenetics, see http://spie.org/ x48167.xml?ArticleID=x48167). Many new opsins have been discovered, including ones that respond to different colors of visible light. Others respond to infrared light. Infrared light is advantageous because it penetrates tissue, and thus, it may eliminate the need for implanting optical fibers to deliver the light pulse to the target tissue. Optogenetic methods have been used to turn on and off cells in many parts of the brain, providing experimenters with new tools to manipulate behavior. A demonstration of the clinical potential of this method comes from a recent study in which optogenetic methods were able to reduce anxiety in mice (Tye et al., 2011). After creating light-sensitive neurons in their amygdala (see Chapter 10), a flash of light was sufficient to motivate the mice to move away from the wall of their home cage and boldly step out into the center. Interestingly, this effect worked only if the light was targeted at a specific subregion of the amygdala. If the entire structure was exposed to the light, the mice remained anxious and refused to explore their cages. Theoretical breakthroughs in all scientific domains can be linked to the advent of new methods and the development of novel instrumentation. Cognitive neuroscience is no exception. It is a field that emerged in part because of the invention of new methods, some of which use advanced tools unavailable to scientists of previous generations (see Chapter 1; Sejnowski & Churchland, 1989). In this chapter, we discuss how these methods work, what information can be derived from them, and their limitations. Many of these methods are shared with other players in the neurosciences, from neurologists

Such experiments employ the various methods that we discuss in this chapter. Experiments cannot prove that a hypothesis is true. Rather, they can provide support for a hypothesis. Even more important, experiments can be used to disprove a hypothesis, providing evidence that a prevailing idea must be modified. By documenting this process and having it repeated again and again, the scientific method allows our understanding of the world to progress.

and neurosurgeons to physiologists and philosophers. Cognitive neuroscience endeavors to take advantage of the insights that each approach has to offer and combine them. By addressing a question from different perspectives and with a variety of techniques, the conclusions arrived at can be made with more confidence. We begin the chapter with cognitive psychology and the behavioral methods it uses to gain insight into how the brain represents and manipulates information. We then turn to how these methods have been used to characterize the behavioral changes that accompany neurological insult or disorder, the subfield traditionally known as neuropsychology. While neuropsychological studies of human patients are dependent on the vagaries of nature, the basic logic of the approach is now pursued with methods in which neural function is deliberately perturbed. We review a range of methods used to perturb neural function. Following this, we turn to more observational methods, first reviewing ways in which cognitive neuroscientists measure neurophysiological signals in either human or animal models, and second, by examining methods in which neural structure and function are inferred through measurements of metabolic and hemodynamic processes. When studying an organ with 11 billion basic elements and gazillions of connections between these elements, we need tools that can be used to organize the data and yield simplified models to evaluate hypotheses. We provide a brief overview of computer modeling and how it has been used by cognitive neuroscientists, and we review a powerful analytical and modeling tool—brain graph theory, which transforms neuroimaging data into models that elucidate the network properties of the human brain. The interdisciplinary nature of cognitive neuroscience has depended on the clever ways in which scientists have integrated paradigms across all of these fields and methodologies. The chapter concludes with examples of this integration. Andiamo!

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Cognitive Psychology and Behavioral Methods Cognitive neuroscience has been informed by the principles of cognitive psychology, the study of mental activity as an information-processing problem. Cognitive psychologists are interested in describing human performance, the observable behavior of humans (and other animals). They also seek to identify the internal processing— the acquisition, storage, and use of information—that underlies this performance. A basic assumption of cognitive psychology is that we do not directly perceive and act in the world. Rather, our perceptions, thoughts, and actions depend on internal transformations or computations. Information is obtained by sense organs, but our ability to comprehend that information, to recognize it as something that we have experienced before and to choose an appropriate response, depend on a complex interplay of processes. Cognitive psychologists design experiments to test hypotheses about mental operations by adjusting what goes into the brain and then seeing what comes out. Put more simply, information is input into the brain, something secret happens to it, and out comes behavior. Cognitive psychologists are detectives trying to figure out what those secrets are. For example, input this text into your brain and let’s see what comes out: ocacdrngi ot a sehrerearc ta maccbriegd ineyurvtis, ti edost’n rttaem ni awth rreod eht tlteser ni a rwdo rea, eht ylon pirmtoatn gihtn si atth het rifts nda satl ttelre eb tat het ghitr clepa. eht srte anc eb a otlta sesm dan ouy anc itlls arde ti owtuthi moprbel. ihst si cebusea eth nuamh nidm sedo otn arde yrvee telrte yb stifle, tub eth rdow sa a lohew. Not much, eh? Now take another shot at it: Aoccdrnig to a rseheearcr at Cmabrigde Uinervtisy, it deosn’t mttaer in waht oredr the ltteers in a wrod are, the olny iprmoatnt tihng is taht the frist and lsat ltteer be at the rghit pclae. The rset can be a total mses and you can sitll raed it wouthit porbelm. Tihs is bcuseae the huamn mnid deos not raed ervey lteter by istlef, but the wrod as a wlohe. Oddly enough, the second version makes sense. It is surprisingly easy to read the second passage, even though only a few words are correctly spelled. As long as the first and last letters of each word are in the correct position, we can accurately infer the correct spelling, especially when the surrounding context helps generate expectations for each word. Simple demonstrations like this one help us discern the content of mental representations,

and thus, help us gain insight into how information is manipulated by the mind. Cognitive neuroscience is distinctive in the study of the brain and behavior, because it combines paradigms developed in cognitive psychology with methods employed to study brain structure and function. Next, we introduce some of those paradigms.

Ferreting Out Mental Representations and Transformations Two key concepts underlie the cognitive approach: 1. Information processing depends on internal representations. 2. These mental representations undergo transformations.

Mental Representations We usually take for granted the idea that information processing depends on internal representations. Consider the concept “ball.” Are you thinking of an image, a word description, or a mathematical formula? Each instance is an alternative form of representing the “circular” or “spherical” concept and depends on our visual system, our auditory system, our ability to comprehend the spatial arrangement of a curved drawing, our ability to comprehend language, or our ability to comprehend geometric and algebraic relations. The context would help dictate which representational format would be most useful. For example, if we wanted to show that the ball rolls down a hill, a pictorial representation is likely to be much more useful than an algebraic formula—unless you are doing your physics final, where you would likely be better off with the formula. A letter-matching task, first introduced by Michael Posner (1986) at the University of Oregon, provides a powerful demonstration that even with simple stimuli, the mind derives multiple representations (Figure 3.2). Two letters are presented simultaneously in each trial. The participant’s task is to evaluate whether they are both vowels, both consonants, or one vowel and one consonant. The participant presses one button if the letters are from the same category, and the other button if they are from different categories. One version of this experiment includes five conditions. In the physical-identity condition, the two letters are exactly the same. In the phonetic-identity condition, the two letters have the same identity, but one letter is a capital and the other is lowercase. There are two types of samecategory conditions, conditions in which the two letters are different members of the same category. In one, both letters are vowels; in the other, both letters are consonants.

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Understanding the Data From the Letter-Matching Task Experiments like the one represented in Figure 3.2 involve manipulating one variable and observing its effect on another variable. The variable that is manipulated is called the independent variable. It is what you (the researcher) have changed. In this example, the relationship of the twoletters is the independent variable, defining the conditions of the experiment (e.g., Identical, Same letter,

Both vowels,etc.). The dependent variable is the event being studied. In this example, it is the response time of the participant. When graphing the results of an experiment, the independent variable is displayed on the horizontal axis (Figure 3.2b) and the dependent variable is displayed on the vertical axis. Experiments can involve more than one independent and dependent variable.

Finally, in the different-category condition, the two letters are from different categories and can be either of the same type size or of different sizes. Note that the first four conditions—physical identity, phonetic identity, and the two same-category conditions—require the “same” response: On all three types of trials, the correct response is that the two letters are from the same category. Nonetheless, as Figure 3.2b shows, response latencies differ significantly. Participants respond fastest to the physical-identity condition, next fastest to the phonetic-identity condition, and slowest to the same-category condition, especially when the two letters are both consonants.

The results of Posner’s experiment suggest that we derive multiple representations of stimuli. One representation is based on the physical aspects of the stimulus. In this experiment, it is a visually derived representation of the shape presented on the screen. A second representation corresponds to the letter’s identity. This representation reflects the fact that many stimuli can correspond to the same letter. For example, we can recognize that A, a, and a all represent the same letter. A third level of abstraction represents the category to which a letter belongs. At this level, the letters A and E activate our internal representation of the category “vowel.” Posner maintains

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Identical

Same letter Aa

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AA a

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FIGURE 3.2 Letter-matching task. (a) Participants press one of two buttons to indicate if the letters are the same or different. The definition of “same” and “different” is manipulated across different blocks of the experiment. (b) The relationship between the two letters is plotted on the x-axis. This relationship is the independent variable, the variable that the experimenter is manipulating. Reaction time is plotted on the y-axis. It is the dependent variable, the variable that the experimenter is measuring.

Different Both Both vowels consonants categories AU SC AS

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that different response latencies reflect the degrees of processing required to perform the letter-matching task. By this logic, we infer that physical representations are activated first, phonetic representations next, and category representations last. As you may have experienced personally, experiments like these elicit as many questions as answers. Why do participants take longer to judge that two letters are consonants than they do to judge that two letters are vowels? Would the same advantage for identical stimuli exist if the letters were spoken? What about if one letter were visual and the other were auditory? Cognitive psychologists address questions like these and then devise methods for inferring the mind’s machinery from observable behaviors. In the letter-matching task, the primary dependent variable was reaction (or response) time, the speed with which participants make their judgments. Reaction time experiments use the chronometric methodology. Chronometric comes from the Greek words chronos (“time”) and metron (“measure”). The chronometric study of the mind is essential for cognitive psychologists because mental events occur rapidly and efficiently. If we consider only whether a person is correct or incorrect on a task, we miss subtle differences in performance. Measuring reaction time permits a finer analysis of the brain’s internal processes.

Internal Transformations The second critical notion of cognitive psychology is that our mental representations undergo transformations. For instance, the transformation of mental representations is obvious when we consider how sensory signals are connected with stored information in memory. For example, a whiff of garlic may transport you to your grandmother’s house or to a back alley in Palermo, Italy. In this instance, an olfactory sensation has somehow been transformed by your brain, allowing this stimulus to call up a memory. Taking action often requires that perceptual representations be translated into action representations in order to achieve a goal. For example, you see and smell garlic bread on the table at dinner. These sensations are transformed into perceptual representations, which are then processed by the brain, allowing you to decide on a course of action and to carry it out—pick up the bread and place it in your mouth. Take note, though, that information processing is not simply a sequential process from sensation to perception to memory to action. Memory may alter how we perceive something. When you see a dog, do you reach out to pet it, perceiving it as cute, or do you draw back in fear, perceiving it as dangerous, having been bitten when you were a child? The manner in which

information is processed is also subject to attentional constraints. Did you register that last sentence, or did all the talk about garlic cause your attention to wander as you made plans for dinner? Cognitive psychology is all about how we manipulate representations.

Characterizing Transformational Operations Suppose you arrive at the grocery store and discover that you forgot to bring your shopping list. You know for sure that you need coffee and milk, the main reason you came; but what else? As you cruise the aisles, scanning the shelves, you hope something will prompt your memory. Is the peanut butter gone? How many eggs are left? This memory retrieval task draws on a number of cognitive capabilities. As we have just learned, the fundamental goal of cognitive psychology is to identify the different mental operations or transformations that are required to perform tasks such as this. Saul Sternberg (1975) introduced an experimental task that bears some similarity to the problem faced by an absentminded shopper. In Sternberg’s task, however, the job is not recalling items stored in memory, but rather comparing sensory information with representations that are active in memory. In each trial, the participant is first presented with a set of letters to memorize (Figure 3.3a). The memory set could consist of one, two, or four letters. Then a single letter is presented, and the participant must decide if this letter was part of the memorized set. The participant presses one button to indicate that the target was part of the memory set (“yes” response) and a second button to indicate that the target was not part of the set (“no” response). Once again, the primary dependent variable is reaction time. Sternberg postulated that, to respond on this task, the participant must engage in four primary mental operations: 1. Encode. The participant must identify the visible target. 2. Compare. The participant must compare the mental representation of the target with the representations of the items in memory. 3. Decide. The participant must decide whether the target matches one of the memorized items. 4. Respond. The participant must respond appropriately for the decision made in step 3. By postulating a set of mental operations, we can devise experiments to explore how these putative mental operations are carried out. A basic question for Sternberg was how to characterize the efficiency of recognition memory. Assuming that all items in the memory set are actively represented, the recognition process might work in one of two ways:

Cognitive Psychology and Behavioral Methods | 77 550 Responses + Yes x No

Reaction time (ms)

525

+ x

500 475 450

+x

425

+ x 400 1 a

2 Number of items in memory set

4

b

FIGURE 3.3 Memory comparison task. (a) The participant is presented with a set of one, two, or four letters and asked to memorize them. After a delay, a single probe letter appears, and the participant indicates whether that letter was a member of the memory set. (b) Reaction time increases with set size, indicating that the target letter must be compared with the memory set sequentially rather than in parallel.

A highly efficient system might simultaneously compare a representation of the target with all of the items in the memory set. On the other hand, the recognition process might be able to handle only a limited amount of information at any point in time. For example, it might require that each item in memory be compared successively to a mental representation of the target. Sternberg realized that the reaction time data could distinguish between these two alternatives. If the comparison process can be simultaneous for all items—what is called a parallel process—then reaction time should be independent of the number of items in the memory set. But if the comparison process operates in a sequential, or serial, manner, then reaction time should slow down as the memory set becomes larger, because more time is required to compare an item with a large memory list than with a small memory list. Sternberg’s results convincingly supported the serial hypothesis. In fact, reaction time increased in a constant, or linear, manner with set size, and the functions for the “yes” and “no” trials were essentially identical (Figure 3.3b). Although memory comparison appears to involve a serial process, much of the activity in our mind operates in parallel. A classic demonstration of parallel processing is the word superiority effect (Reicher, 1969). In this experiment, a stimulus is shown briefly and participants are asked which of two target letters (e.g., A or E) was presented. The stimuli can be composed of words, nonsense letter strings, or letter strings in which every letter is an X

except for the target letter (Figure 3.4). Brief presentation times are used so that errors will be observed, because the critical question centers on whether context affects performance. The word superiority effect (see Figure 3.4 caption) refers to the fact that participants are most accurate in identifying the target letter when the stimuli are words. As we saw earlier, this finding suggests that we do not need to identify all the letters of a word before we recognize the word. Rather, when we are reading a list of words, representations corresponding to the individual letters and to the entire word are activated in parallel for each item. Performance is facilitated because both representations can provide information as to whether the target letter is present.

Does the stimulus contain an A or an E? Condition

Stimulus

Accuracy

Word

R AC K

90%

Nonsense string

KAR C

80%

Xs

X AX X

80%

FIGURE 3.4 Word superiority effect. Participants are more accurate in identifying the target vowel when it is embedded in a word. This result suggests that letter and word levels of representation are activated in parallel.

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Constraints on Information Processing In the memory search experiment, participants are not able to compare the target item to all items in the memory set simultaneously. That is, their processing ability is constrained. Whenever a constraint is identified, an important question to ask is whether the constraint is specific to the system that you are investigating (in this case, memory) or if it is a more general processing constraint. Obviously, people can do only a certain amount of internal processing at any one time, but we also experience task-specific constraints. Processing constraints are defined only by the particular set of mental operations associated with a particular task. For example, although the comparison (item 2 in Sternberg’s list) of a probe item to the memory set might require a serial operation, the task of encoding (item 1 in Sternberg’s list) might occur in parallel, so it would not matter whether the probe was presented by itself or among a noisy array of competing stimuli. Exploring the limitations in task performance is a central concern for cognitive psychologists. Consider a simple color-naming task—devised in the early 1930s by J. R. Stroop, an aspiring doctoral student (1935; for a review, see MacLeod, 1991)—that has become one of the most widely employed tasks in all of cognitive psychology. We will refer to this task many times in this book. The Stroop task involves presenting the participant with a list of words and then asking her to name the color of each word as fast as possible. As Figure 3.5 illustrates, this task is much easier when the words match the ink colors. The Stroop effect powerfully demonstrates the multiplicity of mental representations. The stimuli in this task appear to activate at least two separable representations. One representation corresponds to the color of each stimulus; it is what allows the participant to perform the task. The second representation corresponds to the color concept associated with each word. Participants are slower to name the colors when the ink color and words are mismatched, thus indicating that the second representation is activated, even though it is irrelevant to the task. Indeed, the activation of a representation based on the word rather than the color of the word appears to be automatic. The Stroop effect persists even after thousands of trials of practice, because skilled readers have years of practice in analyzing letter strings for their symbolic meaning. On the other hand, the interference from the words is markedly reduced if the response requires a key press rather than a vocal response. Thus, the word-based representations are closely linked to the vocal response system and have little effect when the responses are produced manually.

Color matches wo rd

C o l o r wi t h o u t wo rd

C o l o r do esn 't m a t c h wo rd

RED

XXXXX

GREEN

GREEN

XXXXX

BLUE

RED

XXXXX

RED

BLUE

XXXXX

BLUE

BLUE

XXXXX

GREEN

GREEN

XXXXX

RED

BLUE

XXXXX

GREEN

RED

XXXXX

BLUE

FIGURE 3.5 Stroop task. Time yourself as you work through each column, naming the color of the ink of each stimulus as fast as possible. Assuming that you do not squint to blur the words, it should be easy to read the first and second columns but quite difficult to read the third.

TAKE-HOME MESSAGES ■

Cognitive psychology focuses on understanding how objects or ideas are represented in the brain and how these representations are manipulated.

Fundamental goals of cognitive psychology include identifying the mental operations that are required to perform cognitive tasks and exploring the limitations in task performance.

Studying the Damaged Brain An integral part of cognitive neuroscience research methodology is choosing the population to be studied. Study populations fall into four broad groups: animals and humans that are neurologically intact, and animals and humans in which the neurological system is abnormal, either as a result of an illness or a disorder, or as a result of experimental manipulation. The population a researcher picks to study depends, at least in part, on the questions being asked. We begin this section with a discussion of the major natural causes of brain dysfunction. Then we consider the different study populations, their limitations, and the methods used with each group.

Studying the Damaged Brain | 79

Causes of Neurological Dysfunction Nature has sought to ensure that the brain remains healthy. Structurally, the skull provides a thick, protective encasement, engendering such comments as “hardheaded” and “thick as a brick.” The distribution of arteries is extensive, ensuring an adequate blood supply. Even so, the brain is subject to many disorders, and their rapid treatment is frequently essential to reduce the possibility of chronic, debilitating problems or death. We discuss some of the more common types of disorders.

Vascular Disorders As with all other tissue, neurons need a steady supply of oxygen and glucose. These substances are essential for the cells to produce energy, fire action potentials, and make transmitters for neural communication. The brain, however, is a hog. It uses 20 % of all the oxygen we breathe, an extraordinary amount considering that it accounts for only 2 % of the total body mass. What’s more, a continuous supply of oxygen is essential: A loss of oxygen for as little as 10 minutes can result in neural death. Angiography is a clinical imaging method used to evaluate the circulatory system in the brain and diagnose disruptions in circulation. As Figure 3.6 shows, this method helps us visualize the distribution of blood by highlighting major arteries and veins. A dye is injected into the vertebral or carotid artery and then an X-ray study is conducted. Cerebral vascular accidents, or strokes, occur when blood flow to the brain is suddenly disrupted. The most frequent cause of stroke is occlusion of the normal

passage of blood by a foreign substance. Over years, atherosclerosis, the buildup of fatty tissue, occurs in the arteries. This tissue can break free, becoming an embolus that is carried off in the bloodstream. An embolus that enters the cranium may easily pass through the large carotid or vertebral arteries. As the arteries and capillaries reach the end of their distribution, however, their size decreases. Eventually, the embolus becomes stuck, or infarcted, blocking the flow of blood and depriving all downstream tissue of oxygen and glucose. Within a short time, this tissue will become dysfunctional. If the blood flow is not rapidly restored, the cells will die (Figure 3.7a). The onset of stroke can be quite varied, depending on the afflicted area. Sometimes the person may lose consciousness and die within minutes. In such cases the infarct is usually in the vicinity of the brainstem. When the infarct is cortical, the presenting symptoms may be striking, such as sudden loss of speech and comprehension. In other cases, the onset may be rather subtle. The person may report a mild headache or feel clumsy in using one of his or her hands. The vascular system is fairly consistent between individuals; thus, stroke of a particular artery typically leads to destruction of tissue in a consistent anatomical location. For example, occlusion of the posterior cerebral artery invariably leads to deficits in visual perception. There are many other types of cerebral vascular disorders. Ischemia can be caused by partial occlusion of an artery or a capillary due to an embolus, or it can arise from a sudden drop in blood pressure that prevents blood from reaching the brain. A sudden rise in blood pressure can lead to cerebral hemorrhage (Figure 3.7b), or bleeding over a wide area of the brain due to the breakage of blood vessels. Spasms in the vessels can result in irregular blood flow and have been associated with migraine headaches. Other disorders are due to problems in arterial structures. Cerebral arteriosclerosis is a chronic condition in which cerebral blood vessels become narrow because of thickening and hardening of the arteries. The result can be persistent ischemia. More acute situations can arise if a person has an aneurysm, a weak spot or distention in a blood vessel. An aneurysm may suddenly expand or even burst, causing a rapid disruption of the blood circulation.

Tumors Brain lesions also can result from tumors. A

FIGURE 3.6 The brain’s blood supply. The angiogram provides an image of the arteries in the brain.

tumor, or neoplasm, is a mass of tissue that grows abnormally and has no physiological function. Brain tumors are relatively common; most originate in glial cells and other supporting white matter tissues. Tumors also can develop from gray matter or neurons, but these are much less common, particularly in adults. Tumors are classified as benign when they do not recur after removal and tend to remain in the area of their germination (although they can become quite large). Malignant, or cancerous, tumors are likely

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b

a

FIGURE 3.7 Vascular disorders of the brain. (a) Strokes occur when blood flow to the brain is disrupted. This brain is from a person who had an occlusion of the middle cerebral artery. The person survived the stroke. After death, a postmortem analysis shows that almost all of the tissue supplied by this artery had died and been absorbed. (b)Coronal section of a brain from a person who died following a cerebral hemorrhage. The hemorrhage destroyed the dorsomedial region of the left hemisphere. The effects of a cerebrovascular accident 2 years before death can be seen in the temporal region of the right hemisphere.

to recur after removal and are often distributed over several different areas. With brain tumors, the first concern is not usually whether the tumor is benign or malignant, but rather its location and prognosis. Concern is greatest when the tumor threatens critical neural structures. Neurons can be destroyed by an infiltrating tumor or become dysfunctional as a result of displacement by the tumor.

Degenerative And Infectious Disorders Many neurological disorders result from progressive disease. Table 3.1 lists some of the more prominent degenerative and infectious disorders. In later chapters, we will review some of

TABLE 3.1

these disorders in detail, exploring the cognitive problems associated with them and how these problems relate to underlying neuropathologies. Here, we focus on the etiology and clinical diagnosis of degenerative disorders. Degenerative disorders have been associated with both genetic aberrations and environmental agents. A prime example of a degenerative disorder that is genetic in origin is Huntington’s disease. The genetic link in degenerative disorders such as Parkinson’s disease and Alzheimer’s disease is weaker. Environmental factors are suspected to be important, perhaps in combination with genetic predispositions.

Prominent Degenerative and Infectious Disorders of the Central Nervous System

Disorder

Type

Most Common Pathology

Alzheimer’s disease

Degenerative

Tangles and plaques in limbic and temporoparietal cortex

Parkinson’s disease

Degenerative

Loss of dopaminergic neurons

Huntington’s disease

Degenerative

Atrophy of interneurons in caudate and putamen nuclei of basal ganglia

Pick’s disease

Degenerative

Frontotemporal atrophy

Progressive supranuclear palsy (PSP)

Degenerative

Atrophy of brainstem, including colliculus

Multiple sclerosis

Possibly infectious

Demyelination, especially of fibers near ventricles

AIDS dementia

Viral infection

Diffuse white matter lesions

Herpes simplex

Viral infection

Destruction of neurons in temporal and limbic regions

Korsakoff’s syndrome

Nutritional deficiency

Destruction of neurons in diencephalon and temporal lobes

Studying the Damaged Brain | 81

a

b

FIGURE 3.8 Degenerative disorders of the brain. (a) Normal brain of a 60-year-old male. (b) Axial slices at four sections of the brain in a 79-year-old male with Alzheimer’s disease. Arrows show growth of white matter lesions.

Although neurologists were able to develop a taxonomy of degenerative disorders before the development of neuroimaging methods, diagnosis today is usually confirmed by MRI scans. The primary pathology resulting from Huntington’s disease or Parkinson’s disease is observed in the basal ganglia, a subcortical structure that figures prominently in the motor pathways (see Chapter 8). In contrast, Alzheimer’s disease is associated with marked atrophy of the cerebral cortex (Figure 3.8). Progressive neurological disorders can also be caused by viruses. The human immunodeficiency virus (HIV) that causes dementia related to acquired immunodeficiency syndrome (AIDS) has a tendency to lodge in subcortical regions of the brain, producing diffuse lesions of the white matter by destroying axonal fibers. The herpes simplex virus, on the other hand, destroys neurons in cortical and limbic structures if it migrates to the brain. Viral infection is also suspected in multiple sclerosis, although evidence for such a link is indirect, coming from epidemiological studies. For example, the incidence of multiple sclerosis is highest in temperate climates, and some isolated tropical islands had not experienced multiple sclerosis until the population came in contact with Western visitors.

Traumatic Brain Injury More than any disease, such as stroke or tumor, most patients arrive on a neurology ward because of a traumatic event such as a car accident, a gunshot wound, or an ill-advised dive into a shallow swimming hole. Traumatic brain injury (TBI) can result from either a closed or an open head injury. In closed head injuries, the skull remains intact, but mechanical forces generated by a blow to the head damage the brain. Common causes of closed head injuries are car accidents and falls, although researchers are now recognizing that closed head TBI can be prevalent in people who have been near a bomb blast or participate in contact sports. The damage may be at the site of the blow, for example,

just below the forehead—damage referred to as a coup. Reactive forces may also bounce the brain against the skull on the opposite side of the head, resulting in a countercoup. Certain regions are especially sensitive to the effects of coups and countercoups. The inside surface of the skull is markedly jagged above the eye sockets; and, as Figure 3.9 shows, this rough surface can produce extensive tearing of brain tissue in the orbitofrontal region. An imaging method, diffusion tensor imaging (discussed later in the chapter), can be used to identify anatomical damage that can result from TBI. For example, using this method, researchers have shown that professional boxers have sustained damage in white matter tracts, even if they never had a major traumatic event (Chappell et al., 2006, Figure 3.10). Similarly, evidence is mounting that the repeated concussions suffered by football and soccer players may cause changes in neural connectivity that produce chronic cognitive problems (Shi et al., 2009). Open head injuries happen when an object like a bullet or shrapnel penetrates the skull. With these injuries, the penetrating object may directly damage brain tissue, and the impact of the object can also create reactive forces producing coup and countercoup. Additional damage can follow a traumatic event as a result of vascular problems and increased risk of infection. Trauma can disrupt blood flow by severing vessels, or it can change intracranial pressure as a result of bleeding. People who have experienced a TBI are also at increased risk for seizure, further complicating their recovery.

Epilepsy Epilepsy is a condition characterized by excessive and abnormally patterned activity in the brain. The cardinal symptom is a seizure, a transient loss of consciousness. The extent of other disturbances varies. Some epileptics shake violently and lose their balance. For others, seizures may be perceptible only to the most attentive friends and family. Seizures are confirmed by electroencephalography

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Traumatic brain injury

a

b

FIGURE 3.9 Traumatic brain injury. Trauma can cause extensive destruction of neural tissue. Damage can arise from the collision of the brain with the solid internal surface of the skull, especially along the jagged surface over the orbital region. In addition, accelerative forces created by the impact can cause extensive shearing of dendritic arbors. (a) In this brain of a 54-year-old man who had sustained a severe head injury 24 years before death, tissue damage is evident in the orbitofrontal regions and was associated with intellectual deterioration subsequent to the injury. (b)The susceptibility of the orbitofrontal region to trauma was made clear by A. Holbourn of Oxford, who in 1943 filled a skull with gelatin and then violently rotated the skull. Although most of the brain retains its smooth appearance, the orbitofrontal region has been chewed up.

(EEG). During the seizure, the EEG profile is marked by large-amplitude oscillations (Figure 3.11). The frequency of seizures is highly variable. The most severely affected patients have hundreds of seizures each

day, and each seizure can disrupt function for a few minutes. Other epileptics suffer only an occasional seizure, but it may incapacitate the person for a couple of hours. Simply having a seizure, however, does not mean a person has epilepsy. Although 0.5 % of the general population has epilepsy, it is estimated that 5 % of people will have a seizure at some point during life, usually triggered by an acute event such as trauma, exposure to toxic chemicals, or high fever.

TAKE-HOME MESSAGES

FIGURE 3.10 Sports-related TBI. Colored regions show white matter tracts that are abnormal in the brains of professional boxers.

Brain lesions, either naturally occurring (in humans) or experimentally derived (in animals), allow experimenters to test hypotheses concerning the functional role of the damaged brain region.

Cerebral vascular accidents, or strokes, occur when blood flow to the brain is suddenly disrupted. Angiography is used to evaluate the circulatory system in the brain.

Tumors can cause neurological symptoms either by damaging neural tissue or by producing abnormal pressure on spared cortex and cutting off its blood supply.

Degenerative disorders include Huntington’s disease, Parkinson’s disease, Alzheimer’s disease, and AIDSrelated dementia.

Neurological trauma can result in damage at the site of the blow (coup) or at the site opposite the blow because

Studying the Damaged Brain | 83 LT

LT

RT

RT

LF

LF

RF

RF

LO

LO RO

RO

a

b

FIGURE 3.11 Electrical activity in a normal and epileptic brain. Electroencephalographic recordings from six electrodes, positioned over the temporal (T), frontal (F), and occipital (O) cortex on both the left (L) and the right (R) sides. (a) Activity during normal cerebral activity. (b) Activity during a grand mal seizure.

of reactive forces (countercoup). Certain brain regions such as the orbitofrontal cortex are especially prone to damage from trauma. ■

Epilepsy is characterized by excessive and abnormally patterned activity in the brain.

Studying Brain–Behavior Relationships Following NeuralDisruption The logic of using participants with brain lesions is straightforward. If a neural structure contributes to a task, then a structure that is dysfunctional through either surgical intervention or natural causes should impair performance of that task. Lesion studies have provided key insights into the relationship between brain and behavior. Fundamental concepts, such as the left hemisphere’s dominant role in language or the dependence of visual functions on posterior cortical regions, were developed by observing the effects of brain injury. This area of research was referred to as behavioral neurology, the province of physicians who chose to specialize in the study of diseases and disorders that affect the structure and function of the nervous system. Studies of human participants with neurological dysfunction have historically been hampered by limited information on the extent and location of the lesion. Two developments in the past half-century, however, have led to significant advances in the study of neurological patients. First, with neuroimaging methods such as computed tomography and magnetic resonance imaging, we can precisely localize brain injury in vivo. Second, the paradigms of cognitive psychology have provided the tools for making more sophisticated analyses of the behavioral deficits observed following brain injury. Early work focused on localizing complex tasks such as

language, vision, executive control, and motor programming. Since then, the cognitive revolution has shaken things up. We know that these complex tasks require integrated processing of component operations that involve many different regions of the brain. By testing patients with brain injuries, researchers have been able to link these operations to specific brain structures, as well as make inferences about the component operations that underlie normal cognitive performance. The lesion method has a long tradition in research involving laboratory animals, in large part because the experimenter can control the location and extent of the lesion. Over the years, surgical and chemical lesioning techniques have been refined, allowing for ever greater precision. Most notable are neurochemical lesions. For instance, systemic injection of 1-methyl-4-phenyl-1,2,3,6tetrahydropyridine (MPTP) destroys dopaminergic cells in the substantia nigra, producing an animal version of Parkinson’s disease (see Chapter 8). Other chemicals have reversible effects, allowing researchers to produce a transient disruption in nerve conductivity. As long as the drug is active, the exposed neurons do not function. When the drug wears off, function gradually returns. The appeal of this method is that each animal can serve as its own control. Performance can be compared during the “lesion” and “nonlesion” periods. We will discuss this work further when we address pharmacological methods. There are some limitations in using animals as models for human brain function. Although humans and many animals have some similar brain structures and functions, there are notable differences. Because homologous structures do not always have homologous functions, broad generalizations and conclusions are suspect. As neuroanatomist Todd Preuss (2001) put it: The discovery of cortical diversity could not be more inconvenient. For neuroscientists, the fact of diversity means that broad generalization about cortical

THE COGNITIVE NEUROSCIENTIST’S TOOLKIT

Study Design: Single and Double Dissociations Percentage correct performing task

a

Single dissociation Controls

100

Temporal lobe damaged 90 Patient group shows impairment on one task and not on the other.

80 70 60 50

b Percentage correct performing task

Consider a study designed to explore the relationship of two aspects of memory: when we learned something and how familiar it is. The study might be designed around the following questions: Is familiarity dependent on our knowledge of when we learned something? Do these two aspects of memory depend on the same brain structures? The working hypothesis could be that these two aspects of memory are separable, and that each is associated with a particular region of the brain. A researcher designs two memory tests: one to look at memory of when information was acquired—“Do you remember when you learned that the World Trade Center Towers had been attacked?” and the second to look at familiarity—“What events occurred and in what order?” Assuming that the study participants were selectively impaired on only one of the two memory tests, our researcher would have observed a single dissociation (Figure 1a). In a single dissociation study, when two groups are each tested on two tasks, a between-group difference is apparent in only one task. Two groups are necessary so that the participants’ performance can be compared with that of a control group. Two tasks are necessary to examine whether a deficit is specific to a particular task or reflects a more general impairment. Many conclusions in neuropsychology are based on single dissociations. Forexample, compared to control participants, patients with hippocampal lesions cannot develop long-term memories even though their short-term memory is intact. In a separate example, patients with Broca’s aphasia have intact comprehension but struggle to speak fluently. Single dissociations have unavoidable problems. In particular, although the two tasks are assumed to be equally sensitive to differences between the control and experimental groups, often this is not the case. One task may be more sensitive than the other because of differences in task difficulty or sensitivity problems in how the measurements are obtained. For example, a task that measures familiarity might require a greater degree of concentration than the one that measures when a memory was learned. If the experimental group has a brain injury, it may have produced a generalized problem in concentration and the patient may have difficulty with the more demanding task. The problem, however, would not be due to a specific memory problem. A double dissociation identifies whether two cognitive functions are independent of each other, something that a single association cannot do. In a double dissociation, group 1 is impaired on task X (but not taskY) and group2 is impaired on task Y (but not task X;

Recency memory

Familiarity memory

Double dissociation Controls

100

Temporal lobe damaged Frontal lobe damaged

90 80

Patient groups show impairment on different tasks.

70 60 50

Recency memory

Familiarity memory

FIGURE 1 Single and double dissociations. (a) In the single dissociation, the patient group shows impairment on one task and not on the other. (b) In the double dissociation, one patient group shows impairment on one task, and a second patient group shows impairment on the other task. Double dissociations provide much stronger evidence for a selective impairment.

Figure1b). Either the performances of the two groups are compared to each other, or more commonly, the patient groups are compared with a control group that shows no impairment in either task. With a double dissociation, it is no longer reasonable to argue that a difference in performance results merely from the unequal sensitivity of the two tasks. In our memory example, the claim that one group has a selective problem with familiarity would be greatly strengthened if it were shown that a second group of patients showed selective impairment on the temporal-order task. Double dissociations offer the strongest neuropsychological evidence that a patient or patient group has a selective deficit in a certain cognitive operation.

Studying the Damaged Brain | 85 organization based on studies of a few “model” species, such as rats and rhesus macaques, are built on weak foundations. In both human and animal studies, the lesion approach itself has limitations. For naturally occurring lesions associated with strokes or tumors, there is considerable variability among patients. Moreover, researchers cannot be confident that the effect of a lesion eliminates the contribution of only a single structure. The function of neural regions that are connected to the lesioned area might also be altered, either because they are deprived of their normal neural input or because their axons fail to make normal synaptic connections. The lesion might also cause the individual to develop a compensatory strategy to minimize the consequences of the lesion. For example, when monkeys are deprived of sensory feedback to one arm, they stop using the limb. However, if the sensory feedback to the other arm is eliminated later, the animals begin to use both limbs (Taub & Berman, 1968). The monkeys prefer to use a limb that has normal sensation, but the second surgery shows that they could indeed use the compromised limb.

The Lesion Approach in Humans Two methodological approaches are available when choosing a study population of participants with brain dysfunction. Researchers can either pick a population with similar anatomical lesions or assemble a population with a similar behavioral deficit. The choice will depend, among other things, on the question being asked. In the box “The Cognitive Neuroscientist’s Toolkit: Study Design,” we consider two possible experimental outcomes that might be obtained in neuropsychological studies, the single and double dissociation. Either outcome can be useful for developing functional models that inform our understanding of cognition and brain function. We also consider in that box the advantages and disadvantages of conducting such studies on an individual basis or by using groups of patients with similar lesions. Lesion studies rest on the assumption that brain injury is eliminative—that brain injury disturbs or eliminates the processing ability of the affected structure. Consider this example. Suppose that damage to brain region A results in impaired performance on task X. One conclusion is that region A contributes to the processing required for task X. For example, if task X is reading, we might conclude that region A is critical for reading. But from cognitive psychology, we know that a complex task like reading has many component operations: fonts must be perceived, letters and letter strings must activate representations of their corresponding meanings, and syntactic operations must link individual words into

a coherent stream. By merely testing reading ability, we will not know which component operation or operations are impaired when there are lesions to region A. What the cognitive neuropsychologist wants to do is design tasks that will be able to test specific hypotheses about brainfunction relationships. If a reading problem stems from a general perceptual problem, then comparable deficits should be seen on a range of tests of visual perception. If the problem reflects the loss of semantic knowledge, then the deficit should be limited to tasks that require some form of object identification or recognition. Associating neural structures with specific processing operations calls for appropriate control conditions. The most basic control is to compare the performance of a patient or group of patients with that of healthy participants. Poorer performance by the patients might be taken as evidence that the affected brain regions are involved in the task. Thus, if a group of patients with lesions in the frontal cortex showed impairment on our reading task, we might suppose that this region of the brain was critical for reading. Keep in mind, however, that brain injury can produce widespread changes in cognitive abilities. Besides having trouble reading, the frontal lobe patient might also demonstrate impairment on other tasks, such as problem solving, memory, or motor planning. Thus the challenge for the cognitive neuroscientist is to determine whether the observed behavioral problem results from damage to a particular mental operation or is secondary to a more general disturbance. For example, many patients are depressed after a neurological disturbance such as a stroke, and depression is known to affect performance on a wide range of tasks.

Functional Neurosurgery: Intervention to Alter or Restore Brain Function Surgical interventions for treating neurological disorders provide a unique opportunity to investigate the link between brain and behavior. The best example comes from research involving patients who have undergone surgical treatment for the control of intractable epilepsy. The extent of tissue removal is always well documented, enabling researchers to investigate correlations between lesion site and cognitive deficits. But caution must be exercised in attributing cognitive deficits to surgically induced lesions. Because the seizures have spread beyond the epileptogenic tissue, other structurally intact tissue may be dysfunctional owing to the chronic effects of epilepsy. One method used with epilepsy patients compares their performance before and after surgery. The researcher can differentiate changes associated with the surgery from those associated with

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the epilepsy. An especially fruitful paradigm for cognitive neuroscience has involved the study of patients who have had the fibers of the corpus callosum severed. In these patients, the two hemispheres have been disconnected—a procedure referred to as a callosotomy operation or, more informally, the split-brain procedure. The relatively few patients who have had this procedure have been studied extensively, providing many insights into the roles of the two hemispheres on a wide range of cognitive tasks. These studies are discussed more extensively in Chapter 4. In the preceding examples, neurosurgery was eliminative in nature, but it has also been used as an attempt to restore normal function. Examples are found in current treatments for Parkinson’s disease, a movement disorder resulting from basal ganglia dysfunction. Although the standard treatment is medication, the efficacy of the drugs can change over time and even produce debilitating side effects. Some patients who develop severe side effects are now treated surgically. One widely used technique is deep-brain stimulation (DBS), in which electrodes are implanted in the basal ganglia. These devices produce continuous electrical signals that stimulate neural activity. Dramatic and sustained improvements are observed in many patients (Hamani et al., 2006; Krack et al., 1998), although why the procedure works is not well understood. There are side effects, in part because more than one type of neuron is stimulated. Optogenetics methods promise to provide an alternative method in which clinicians can control neural activity. While there are currently no human applications, this method has been used to explore treatments of Parkinson’s symptoms in a mouse model of the disease. Early work here suggests that the most effective treatments may not result from the stimulation of specific cells, but rather the way in which stimulation changes the interactions between different types of cells (Kravitz et al., 2010). This finding underscores that many diseases of the nervous system are not usually related to problems with neurons per se, but rather with how the flow of information is altered by the disease process.

TAKE-HOME MESSAGES ■

Research involving patients with neurological disorders is used to examine structure–function relationships. Single and double dissociations can provide evidence that damage to a particular brain region may result in a selective deficit of a certain cognitive operation.

Surgical procedures have been used to treat neurological disorders such as epilepsy or Parkinson’s disease. Studies conducted in patients before and after surgery have provided unique opportunities to study brainbehavior relationships.

Methods to Perturb Neural Function As mentioned earlier, patient research rests on the assumption that brain injury is an eliminative process. The lesion is believed to disrupt certain mental operations while having little or no impact on others. The brain is massively interconnected, however, so just as with lesion studies in animals, structural damage in one area might have widespread functional (i.e., behavioral) consequences; or, through disruption of neural connections, the functional impact might be associated with a region of the brain that was not itself directly damaged. There is also increasing evidence that the brain is a plastic device: Neural function is constantly being reshaped by our experiences, and such reorganization can be quite remarkable following neurological damage. Consequently, it is not always easy to analyze the function of a missing part by looking at the operation of the remaining system. You don’t have to be an auto mechanic to understand that cutting the spark plug wires or cutting the gas line will cause an automobile to stop running, but this does not mean that spark plug wires and the gas line do the same thing; rather, removing either one of these parts has similar functional consequences. Many insights can be gleaned from careful observations of people with neurological disorders, but as we will see throughout this book, such methods are, in essence, correlational. Concerns like these point to the need for methods that involve the study of the normal brain. The neurologically intact participant, both human and nonhuman, is used, as we have already noted, as a control when studying participants with brain injuries. Neurologically intact participants are also used to study intact function (discussed later in this chapter) and to investigate the effects of transient perturbations to the normal brain, which we discuss next. One age-old method of perturbing function in both humans and animals is one you may have tried yourself: the use of drugs, whether it be coffee, chocolate, beer, or something stronger. Newer methods include transcranial magnetic stimulation and transcranial direct current stimulation. Genetic methods, used in animal models, provide windows into the molecular mechanisms that underpin brain function. Genomic analysis can also help identify the genetic abnormalities that contribute to certain diseases, such as Huntington’s. And of course, optogenetics, which opened this chapter, has enormous potential for understanding brain structure–function connections as well as managing or curing some devastating diseases. We turn now to the methods used to perturb function, both at the neurologic and genetic levels, in normal participants.

Methods to Perturb Neural Function | 87

Pharmacology The release of neurotransmitters at neuronal synapses and the resultant responses are critical for information transfer from one neuron to the next. Though protected by the blood–brain barrier (BBB), the brain is not a locked compartment. Many different drugs, known as psychoactive drugs (e.g., caffeine, alcohol, and cocaine as well as the pharmaceutical drugs used to treat depression and anxiety), can disturb these interactions, resulting in changes in cognitive function. Pharmacological studies may involve the administration of agonist drugs, those that have a similar structure to a neurotransmitter and mimic its action, or antagonist drugs, those that bind to receptors and block or dampen neurotransmission. For the researcher studying the impacts of pharmaceuticals on human populations, there are “native” groups to study, given the prevalence of drug use in our culture. For example, in Chapter 12 we examine studies of cognitive impairments associated with chronic cocaine abuse. Besides being used in studies of chronic drug users, neurologically intact populations are used for studies in which researchers administer a drug in a controlled environment and monitor its effects on cognitive function. For instance, the neurotransmitter dopamine is known to be a key ingredient in reward-seeking behavior. One

study looked at the effect of dopamine on decision making when a potential monetary reward or loss was involved. One group of participants received the dopamine receptor antagonist haloperidol; another received the receptor agonist L-DOPA, the metabolic precursor of dopamine (though dopamine itself is unable to cross the BBB, L-DOPA can and is then converted to dopamine). Each group performed a computerized learning task, in which they were presented with a choice of two symbols on each trial. They had to choose between the symbols with the goal of maximizing payoffs (Figure 3.12; Pessiglione et al., 2006). Each symbol was associated with a certain unknown probability of gain or no gain, loss or no loss, or no gain or loss. For instance, a squiggle stood an 80 % chance of winning a pound and a 20 % chance of winning nothing, but a figure eight stood an 80 % of losing a pound and a 20 % chance of no loss, and a circular arrow resulted in no win or loss. On gain trials, the L-DOPA-treated group won more money than the haloperidol-treated group, whereas on loss trials, the groups did not differ. These results are consistent with the hypothesis that dopamine has a selective effect on reward-driven learning. A major drawback of drug studies in which the drug is injected into the bloodstream is the lack of specificity. The entire body and brain are awash in the drug, so it is unknown how much drug actually makes it to the site of

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FIGURE 3.12 Pharmacological manipulation of reward-based learning. (a) Participants chose the upper or lower of two abstract visual stimuli and observed the outcome. Theselected stimulus, circled in red, is associated with an 80% chance of winning $1 and a 20% chance of winning nothing. The probabilities are different for other stimuli. (b)Learning functions showing probability of selecting stimuli associated with gains (circles) or avoid stimuli associated with losses (squares) as a function of the number of times each stimulus was presented. Participants given L-DOPA (green), a dopamine agonist, were faster in learning to choose stimuli associated with gains, compared to participants given a placebo (gray). Participants given haloperidol (red), a dopamine antagonist, were slower in leaning to choose the gain stimuli. The drugs did not affect how quickly participants learned to avoid the stimuli associated with a cost.

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interest in the brain. In addition, the potential impact of the drug on other sites in the body and the dilution effect confound data analysis. In some animal studies, direct injection of a study drug to specific brain regions helps obviate this problem. For example, Judith Schweimer (2006) examined the brain mechanisms involved in deciding how much effort an individual should expend to gain a reward. Do you stay on the couch and watch a favorite TV show, or get dressed up to go out to a party and perhaps make a new friend? Earlier work showed that rats depleted of dopamine are unwilling to make effortful responses that are highly rewarding (Schweimer et al., 2005) and that the anterior cingulate cortex (ACC), a part of the prefrontal cortex, is important for evaluating the cost versus benefit of performing an action (Rushworth et al., 2004). Knowing that there are two types of dopamine receptors in the ACC, called D1 and D2, Schweimer wondered which was involved. In one group of rats, she injected a drug into the ACC that blocked the D1 receptor; in another, she injected a D2 antagonist. The group that had their D1 receptors blocked turned out to act like couch potatoes, but the rats with blocked D2 receptors were willing to make the effort to pursue the high reward. This dissociation indicates that dopamine input to the D1 receptors within the ACC is critical for effort-based decision making.

Transcranial magnetic stimulation (TMS) offers a method to noninvasively produce focal stimulation of the human brain. The TMS device consists of a tightly wrapped wire coil, encased in an insulated sheath and connected to a source of powerful electrical capacitors. Triggering the capacitors sends a large electrical current through the coil, generating a magnetic field. When the coil is placed on the surface of the skull, the magnetic field passes through the skin and scalp and induces a physiological current that causes neurons to fire (Figure 3.13a). The exact mechanism causing the neural discharge is not well understood. Perhaps the current leads to the generation of action potentials in the soma; alternatively, the current may directly stimulate axons.

The area of neural activation will depend on the shape and positioning of the coil. With currently available coils, the area of primary activation can be constrained to about 1.0 to 1.5 cm3, although there are also downstream effects (see Figure 3.13b). When the TMS coil is placed over the hand area of the motor cortex, stimulation will activate the muscles of the wrist and fingers. The sensation can be rather bizarre. The hand visibly twitches, yet the participant is aware that the movement is completely involuntary! Like many research tools, TMS was originally developed for clinical purposes. Direct stimulation of the motor cortex provides a relatively simple way to assess the integrity of motor pathways because muscle activity in the periphery can be detected about 20 milliseconds (ms) after stimulation. TMS has also become a valuable research tool in cognitive neuroscience because of its ability to induce “virtual lesions” (Pascual-Leone et al., 1999). By stimulating the brain, the experimenter is disrupting normal activity in a selected region of the cortex. Similar to the logic in lesion studies, the behavioral consequences of the stimulation are used to shed light on the normal function of the disrupted tissue. This method is appealing because the technique, when properly conducted, is safe and noninvasive, producing only a relatively brief alteration in neural activity. Thus, performance can be compared between stimulated and nonstimulated conditions in the same individual. This, of course, is not possible with brain-injured patients. The virtual-lesion approach has been successfully employed even when the person is unaware of any effects from the stimulation. For example, stimulation over visual cortex (Figure 3.14) can interfere with a person’s ability to identify a letter (Corthout et al., 1999). The synchronized discharge of the underlying visual neurons interferes with their normal operation. The timing between the onset of the TMS pulse and the onset of the stimulus (e.g., presentation of a letter) can be manipulated to plot the time course of processing. In the letter identification task, the person will err only if the stimulation occurs between 70 and 130 ms after presentation of the letter. If the TMS is given before this interval, the neurons have time to recover; if the TMS is given after this interval, the visual neurons have already responded to the stimulus.

a

FIGURE 3.13 Transcranial magnetic stimulation. (a) The TMS coil is held by the experimenter against the participant’s head. Both the coil and the participant have affixed to them a tracking device to monitor the head and coil position in real time. (b)The TMS pulse directly alters neural activity in a spherical area of approximately 1 cm3.

Transcranial Magnetic Stimulation

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Methods to Perturb Neural Function | 89

Proportion correct

become hyperpolarized and are less likely to fire. tDCS will alter neural activity over a much larger area than is directly affected by a TMS pulse. tDCS has been shown to produce changes in behavioral performance. The effects can sometimes be observed within a single experimental session. a Anodal tDCS generally leads to improvements in performance, 1.0 perhaps because the neurons are put into a more excitable 0.8 state. Cathodal stimulation may hinder performance, akin 0.6 to TMS, although the effects of cathodal stimulation are generWhen the pulse follows the 0.4 ally less consistent. tDCS has stimulus by 70 to 130 ms, the participant fails to identify also been shown to produce 0.2 the stimulus on a large beneficial effects for patients percentage of the trials. with various neurological con0.0 ditions such as stroke or chron–100 –80 –60 –40 –20 0 20 40 60 80 100 120 140 160 180 ic pain. The effects tend to be Pulse before stimulus (ms) Pulse after stimulus (ms) b short-lived, lasting for just a FIGURE 3.14 Transcranial magnetic stimulation over the occipital lobe. half hour beyond the stimula(a) The center of the coil is positioned over the occipital lobe to disrupt visual processing. The tion phase. If repeatedly apparticipant attempts to name letters that are briefly presented on the screen. A TMS pulse is plied, however, the duration of applied on some trials, either just before or just after the letter. (b) The independent variable is the the benefit can be prolonged time between the TMS pulse and letter presentation. Visual perception is markedly disrupted when the pulse occurs 80–120 ms after the letter due to disruption of neural activity in the visual cortex. from minutes to weeks (Boggio There is also a drop in performance if the pulse comes before the letter. This is likely an artifact et al., 2007). due to the participant blinking in response to the sound of the TMS pulse. TMS and tDCS give cognitive neuroscientists safe methods for transiently disrupting the activity of the human brain. An appealing feature of these methods is that researchers can design experiments to test specific functional hypotheses. Unlike neuropsychological studies in which comparisons are usually between a patient group and Transcranial direct current stimulation (tDCS) is a matched controls, participants in TMS and tDCS studies brain stimulation procedure that has been around in some can serve as their own controls, since the effects of these form for the last two thousand years. The early Greeks stimulation procedures are transient. and Romans used electric torpedo fish, which can deliver from 8 to 220 volts of DC electricity, to stun and numb patients in an attempt to alleviate pain, such as during childbirth and migraine headache episodes. Today’s electrical stimulation uses a much smaller current (1–2 mV) The start of the 21st century witnessed the climax of one that feels like a tingling or itchy feeling when it is turned of the great scientific challenges: the mapping of the huon or off. tDCS sends a current between two small elecman genome. Scientists now possess a complete record trodes—an anode and a cathode—placed on the scalp. of the genetic sequence on our chromosomes. We have Physiological studies show that neurons under the anonly begun to understand how these genes code for all ode become depolarized. That is, they are put into an aspects of human structure and function. In essence, we elevated state of excitability, making them more likely now have a map containing the secrets to many treasures: to initiate an action potential when a stimulus or moveWhat causes people to grow old? Why are some people ment occurs (see Chapter 2). Neurons under the cathode more susceptible to certain cancers than other people?

Transcranial Direct Current Stimulation

Genetic Manipulations

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What dictates whether embryonic tissue will become a skin cell or a brain cell? Deciphering this map is an imposing task that will take years of intensive study. Genetic disorders are manifest in all aspects of life, including brain function. As noted earlier, diseases such as Huntington’s disease are clearly heritable. By analyzing individuals’ genetic codes, scientists can now predict whether the children of individuals carrying the HD gene will develop this debilitating disorder. Moreover, by identifying the genetic locus of this disorder, scientists hope to devise techniques to alter the aberrant genes, either by modifying them or by figuring out a way to prevent them from being expressed. In a similar way, scientists have sought to understand other aspects of normal and abnormal brain function through the study of genetics. Behavioral geneticists have long known that many aspects of cognitive function are heritable. For example, controlling mating patterns on the basis of spatial-learning performance allows the development of “maze-bright” and “maze-dull” strains of rats. Rats that quickly learn to navigate mazes are likely to have offspring with similar abilities, even if the offspring are raised by rats that are slow to navigate the same mazes. Such correlations are also observed across a range of human behaviors, including spatial reasoning, reading speed, and even preferences in watching television (Plomin et al., 1990). This finding should not be taken to mean that our intelligence or behavior is genetically determined. Maze-bright rats perform quite poorly if raised in an impoverished environment. The truth surely reflects complex interactions between the environment and genetics (see “The Cognitive Neuroscientist’s Toolkit: Correlation and Causation”).

To understand the genetic component of this equation, neuroscientists are now working with many animal models, seeking to identify the genetic mechanisms of both brain structure and function. Dramatic advances have been made in studies with model organisms like the fruit fly and mouse, two species with reproductive propensities that allow many generations to be spawned in a relatively short time. As with humans, the genomes for these species have been sequenced, which has provided researchers the opportunity to explore the functional role of many genes. A key methodology is to develop genetically altered animals, using what are referred to as knockout procedures. The term knockout comes from the fact that specific genes have been manipulated so that they are no longer present or expressed. Scientists can then study the knockout strains to explore the consequences of these changes. For example, weaver mice are a knockout strain in which Purkinje cells, the prominent cell type in the cerebellum, fail to develop. As the name implies, these mice exhibit coordination problems. At an even more focal level, knockout procedures have been used to create strains that lack a single type of postsynaptic receptor in specific brain regions, while leaving intact other types of receptors. Susumu Tonegawa at the Massachusetts Institute of Technology (MIT) and his colleagues developed a mouse strain in which N-methyl-D-aspartate (NMDA) receptors were absent in cells within a subregion of the hippocampus (Wilson & Tonegawa, 1997; also see Chapter 9). Mice lacking these receptors exhibited poor learning on a variety of memory tasks, providing a novel approach for linking memory with its molecular substrate (Figure 3.15). In a sense, this approach constitutes a lesion method, but at a microscopic level.

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FIGURE 3.15 Fear conditioning in knockout mice. Brain slices through the hippocampus, showing the absence of a particular receptor in genetically altered mice (CTX = cortex; DG = dentate gyrus; ST = striatum). (a) Cells containing the gene associated with the receptor are stained in black. (b) These cells are absent in the CA1 region of the slice from the knockout mouse. (c) Fear conditioning is impaired in knockout mice. After receiving a shock, the mice freeze. When normal mice are placed in the same context 24 hours later, they show strong learning by the large increase in the percentage of freezing responses. This increase is reduced in the knockout mice.

24-hour retention

Structural Analysis of theBrain | 91 Neurogenetic research is not limited to identifying the role of each gene individually. Complex brain function and behavior arise from interactions between many genes and the environment. As our genetic tools become more sophisticated, scientists will be better positioned to detect the polygenetic influences on brain function and behavior.

TAKE-HOME MESSAGES ■

Brain function can be perturbed by drugs, magnetic orelectrical stimulation, and through genetic manipulations.

A major drawback of drug studies, in which the drug isinjected into the bloodstream, is the lack of specificity.

Transcranial magnetic stimulation (TMS) uses magnetic pulses to transiently alter local brain physiology.

Structural Analysis of theBrain We now turn to the methods used to analyze brain structure. Structural methods take advantage of the differences in physical properties that different tissues possess. For instance, when you look at an X-ray, the first thing you notice is that bones appear starkly white and the surrounding structures vary in intensity from black to white. The density of biological material varies, and the absorption of X-ray radiation is correlated with tissue density. In this section, we introduce computed tomography (CT), magnetic resonance imaging (MRI), and diffusion tensor imaging (DTI).

Computed Tomography

Computed tomography (CT or CAT scanning), introduced commercially in 1983, has been an extremely im■ Gene knockout technology allows scientists to portant medical tool for structural imaging of neurological explorethe consequences of the lack of expression damage in patients. While conventional X-rays compress ofa specific gene in order to determine its role in three-dimensional objects into two dimensions, CT scanbehavior. ning allows for the reconstruction of three-dimensional space from compressed two-dimensional images. Figure 3.16a depicts the method, showing how X-ray beams are passed through the head and a two-dimensional (2-D) image is generated by sophisticated computer X-ray tube software. The sides of the CT scanner rotate, X-ray beams are sequentially projected, and 2-D images are collected over a 180° arc. Finally, a Detector computer constructs a threedimensional X-ray image from the series of 2-D images. Figure 3.16b shows a CT scan of a healthy individual. Most of the cortex and white matter appear as homogeneous gray areas. The typical spatial resolution for X-ray beam CT scanners is approximately 0.5 to 1.0 cm in all directions. b a Each point on the image reflects an average density of FIGURE 3.16 Computed tomography provides an important tool for imaging neurological pathology. that point and the surroundAs with standard clinical X-rays, the absorption of X-ray radiation in a CT scan is correlated with tissue density. High-density material, such as bone, absorbs a lot of radiation and appears white. Low-density ing 1.0 mm of tissue. Thus, it material, such as air or cerebrospinal fluid, absorbs little radiation. The absorption capacity of neural is not possible to discriminate tissue lies between these extremes. (a) The CT process is based on the same principles as X-rays. An two objects that are closer X-ray is projected through the head, and the recorded image provides a measurement of the density of than approximately 5 mm. the intervening tissue. By projecting the X-ray from multiple angles combined with the use of computer Because the cortex is only algorithms, a three-dimensional image based on tissue density is obtained. (b) In this transverse CT 4 mm thick, it is very difficult image, the dark regions along the midline are the ventricles, the reservoirs of cerebrospinal fluid.

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Correlation and Causation: Brain Size and PTSD reasonable, there are certainly alternative ways to account for the relationship between drinking and income. For example, individuals who make a lot of money can afford to go to bars at night and spend their income on drinks. In elementary statistics courses, we learn to be wary about inferring causation from correlation, but the temptation can be strong. The tendency to infer causation from correlation can be especially great when we’re comparing the contribution of nature and nurture to brain and behavior. A good example comes from work examining the relationship of chronic stress and the hippocampus, a part of the brain

The issue of causation is important to consider in any discussion of scientific observation. Consider a study that examined the relationship between drinking habits and personal income (Peters & Stringham, 2006). Selfreported drinkers earned about 10% more than selfreported abstainers. Those who drank in bars earned an additional 7%. The research team offered the counterintuitive conclusion that the increase in alcohol consumption played a causative role in the higher income levels, at least in men. In their view, social drinking increases social networking, and this networking has the benefit of increasing income. Although this causal chain is

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Figure 1 Exploring the relationship between PTSD and hippocampal size. Scatter plots illustrate the relationship of symptom severity in combat veterans with PTSD to (a) their own hippocampal volumes and (b) the hippocampal volumes of their identical twin brothers who were not exposed to combat. Symptom severity represents the total score received on the ClinicianAdministered PTSD Scale(CAPS).

to see the boundary between white and gray matter on a CT scan. The white and gray matter are also of very similar density, further limiting the ability of this technique to distinguish them. Larger structures, however, can be identified easily. The surrounding skull appears white due to the high density of bone. The ventricles are black owing to the low density of cerebrospinal fluid.

Magnetic Resonance Imaging Although CT machines are still widely used, many hospitals now also own a magnetic resonance imaging (MRI) scanner, which can produce high-resolution images of soft tissue. MRI exploits the magnetic properties of atoms that make up organic tissue. One such atom that is pervasive in the brain, and indeed in all organic tissue, is hydrogen.

The proton in a hydrogen atom is in constant motion, spinning about its principal axis. This motion creates a tiny magnetic field. In their normal state, the orientation of a population of protons in tissue is randomly distributed, unaffected by the weak magnetic field created by Earth’s gravity (Figure 3.17). The MRI scanner creates a powerful magnetic field, measured in tesla units. Whereas gravitational forces on the Earth create a magnetic field of about 0.001 tesla, the typical MRI scanner produces a magnetic field from 0.5 to 1.5 teslas. When a person is placed within the magnetic field of the MRI machine, a significant proportion of their protons become oriented in the direction parallel to the strong magnetic force of the MRI machine. Radio waves are then passed through the magnetized regions, and as the protons absorb the energy in these waves, their orientation is perturbed in a

Structural Analysis of theBrain | 93

that is critical for learning and memory. From animal studies, we know that exposure to prolonged stress, and the resulting increase in glucocorticoid steroids, can cause atrophy in the hippocampus (Sapolsky et al., 1990). With the advent of neuroimaging, we have also learned that people with chronic posttraumatic stress disorder (PTSD) have smaller hippocampi then individuals who do not suffer from PTSD (Bremner et al., 1997; M. B. Stein et al., 1997). Can we therefore conclude that the stress that we know is associated with PTSD results, over time, in a reduction in the hippocampal volume of people with PTSD? This certainly seems a reasonable way to deduce a causal chain of events between these observations. It is also important, however, to consider alternative explanations. For instance, the causal story may run in the opposite direction: Individuals with smaller hippocampi, perhaps due to genetic variation, may be more vulnerable to the effects of stress, and thus be at higher risk for developing PTSD. What study design could distinguish between two hypotheses—one that emphasizes environmental factors (e.g., PTSD, via chronic stress, causes reduction in size of the hippocampus) and one that emphasizes genetic factors (e.g., individuals with small hippocampi are at risk for developing PTSD)? A favorite approach of behavioral geneticists in exploring questions like these is to study identical twins. Mark Gilbertson and his colleagues (2002) at the New Hampshire Veterans Administration Medical Center studied a cohort of 40 pairs of identical twins. Within each twin pair,

one member had experienced severe trauma during a tour of duty in Vietnam. The other member of the pair had not seen active duty. In this way, each high-stress participant had a very well-matched control, at least in terms of genetics: an identical twin brother. Although all of the active-duty participants had experienced severe trauma during their time in Vietnam (one of the inclusion criteria for the study), not all of these individuals had developed PTSD. Thus, the experimenters could look at various factors associated with the onset of PTSD in a group of individuals with similar environmental experiences. Consistent with previous studies, anatomical MRIs showed that people with PTSD had smaller hippocampi than unrelated individuals without PTSD had. The same was also found for the twin brothers of the individuals with PTSD; that is, these individuals also had smaller hippocampi, even though they did not have PTSD and did not report having experienced unusual trauma in their lifetime. Moreover, the severity of the PTSD was negatively correlated with the size of the hippocampus in both the patient with PTSD (Figure 1a) and the matched twin control (Figure 1b). Thus, the researchers concluded that small hippocampal size was a risk factor for developing PTSD and that PTSD alone did not cause the decreased hippocampal size. This study serves as an example of the need for caution: Experimenters must be careful when making causal inferences based on correlational data. This study also provides an excellent example of how scientists are studying interactions between genes and the environment in influencing behavior and brain structure.

predictable direction. When the radio waves are turned off, the absorbed energy is dissipated and the protons rebound toward the orientation of the magnetic field. This synchronized rebound produces energy signals that are picked up by detectors surrounding the head of the participant. By systematically measuring the signals throughout the three-dimensional volume of the head, an MRI system can then construct an image based on the distribution of the protons and other magnetic agents in the tissue. The hydrogen proton distribution is determined largely by the distribution of water throughout the brain, enabling MRI to distinguish clearly the brain’s gray matter, white matter, ventricles, and fiber tracts. As Figure 3.17b shows, MRI scans provide a much clearer image of the brain than is possible with CT scans. This improvement occurs because the density of protons

is much greater in gray matter compared to white matter. With MRI, it is easy to see the individual sulci and gyri of the cerebral cortex. A sagittal section at the midline reveals the impressive size of the corpus callosum. The MRI scans can resolve structures that are much smaller than 1 mm, allowing elegant views of small, subcortical structures such as the mammillary bodies or superior colliculus.

Diffusion Tensor Imaging A variant of traditional MRI scanners is now used to study the anatomical structure of the axon tracts that form the brain’s white matter; that is, it can offer information about anatomical connectivity between regions. This method, called diffusion tensor imaging (DTI), is performed with an MRI scanner that measures the density

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In normal state, the orientation of spinning protons is randomly distributed.

Exposure to the magnetic field of the MRI scanner aligns the orientation of the protons.

a

When a radio frequency pulse is applied, the axes of the protons are shifted in a predictable manner and put the protons in an elevated energy state.

When the pulse is turned off, the protons release their energy as they spin back to the orientation of the magnetic field.

b FIGURE 3.17 MRI. Magnetic resonance imaging exploits the fact that many organic elements, such as hydrogen, are magnetic. (a) In their normal state, the orientation of these hydrogen atom nuclei (i.e., protons) is random. When an external magnetic field is applied, the protons align their axis of spin in the direction of the magnetic field. A pulse of radio waves (RF) alters the spin of the protons as they absorb some of the RF energy. When the RF pulse is turned off, the protons emit their own RF energy, which is detected by the MRI machine. The density of hydrogen atoms is different in white and gray matter, making it easy to visualize these regions. (b)Transverse, coronal, and sagittal images. Comparing the transverse slice in this figure with the CT image in Figure 3.16 reveals the finer resolution offered by MRI. Both images are from about the same level of the brain.

and the motion of the water contained in the axons. DTI uses the known diffusion characteristics of water to determine the boundaries that restrict water movement throughout the brain (Behrens et al., 2003). Free diffusion of water is isotropic; that is, it occurs equally in all directions. Diffusion of water in the brain, however, is anisotropic, or restricted, so it does not diffuse equally in all directions. The reason for this anisotropy is that the axon membranes restrict the diffusion of water; the probability of water moving in the direction of the axon is thus greater than the probability of water moving perpendicular to the axon (Le Bihan, 2003). Within the brain, this anisotropy is greatest in axons because myelin creates a nearly pure lipid boundary, which limits the flow of water

much more than gray matter or cerebrospinal fluid does. In this way, the orientation of axon bundles within the white matter can be imaged (DaSilva et al., 2003). MRI principles can be combined with what is known about the diffusion of water to determine the diffusion anisotropy within the MRI scan. By introducing two large pulses to the magnetic field, MRI signals can be made sensitive to the diffusion of water (Le Bihan, 2003). The first pulse determines the initial position of the protons carried by water. The second pulse, introduced after a short delay, detects how far the protons have moved in space in the specific direction being measured. Since the flow of water is constrained by the axons, the resulting image reveals the major white matter tracts (Figure 3.18).

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FIGURE 3.18 Diffusion tensor imaging. (a) This axial slice of a human brain reveals the directionality and connectivity of the white matter. The colors correspond to the principal directions of the white matter tracts in each region. (b)DTI data can be analyzed to trace white matter connections in the brain. The tracts shown here form the inferior fronto-occipital fasciculus, which, as the name suggests, connects the visual cortex to the frontal lobe.

a

TAKE-HOME MESSAGES ■

Computed tomography (CT or CAT) uses X-rays to image the 3-D structure of the brain.

Magnetic resonance imaging (MRI) exploits the magnetic properties of the organic tissue of the brain to image its structure. The spatial resolution of MRI is superior to CT.

Diffusion tensor imaging (DTI), performed with magnetic resonance scanners, is used to measure white matter pathways in the brain and thus can offer information about anatomical connectivity between regions.

Methods for the Study of Neural Function The development of electrodes and recording systems that can measure the electrical activity within a single neuron or from a small group of neurons was a turning point for neurophysiology and related fields. We open this section with a brief discussion of the single-cell recording method and provide some examples of how it is used to understand cognitive functions. We then turn to the blossoming number of methods used to study brain function during cognitive processing. In this section, we introduce some of the technologies that allow researchers to directly observe the electrical activity of the healthy brain in vivo. After that, we turn to methods that measure physiological changes resulting from neural activity and, in particular, changes in blood flow and oxygen utilization that arise when neural activity increases.

Single-Cell Recording in Animals The most important technological advance in neurophysiology—perhaps in all of neuroscience—was the

b

development of methods to record the activity of single neurons in laboratory animals. With these methods, the understanding of neural activity advanced by a quantum leap. No longer did the neuroscientist have to be content with describing nervous system action in terms of functional regions. Single-cell recording enabled researchers to describe the response characteristics of individual elements. In single-cell recording, a thin electrode is inserted into an animal’s brain. When the electrode is in the vicinity of a neuronal membrane, changes in electrical activity can be measured (see Chapter 2). Although the surest way to guarantee that the electrode records the activity of a single cell is to record intracellularly, this technique is difficult, and penetrating the membrane frequently damages the cell. Thus single-cell recording is typically done extracellularly, with the electrode situated on the outside of the neuron. There is no guarantee, however, that the changes in electrical potential at the electrode tip reflect the activity of a single neuron. More likely, the tip will record the activity of a small set of neurons. Computer algorithms are subsequently used to differentiate this pooled activity into the contributions from individual neurons. The neurophysiologist is interested in what causes change in the synaptic activity of a neuron. She seeks to determine the response characteristics of individual neurons by correlating their activity with a given stimulus pattern or behavior. The primary goal of single-cell recording experiments is to determine what experimental manipulations produce a consistent change in the response rate of an isolated cell. For instance, does the cell increase its firing rate when the animal moves its arm? If so, is this change specific to movements in a particular direction? Does the firing rate for that movement depend on the outcome of the action (e.g., a food morsel to be reached or an itch to be scratched)? Equally interesting, what makes the cell decrease its response rate? These measurements of

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The data from single-cell recording studies is commonly graphed as a raster plot, which shows action potentials as a function of time (Figure 1). The graph includes data from before the start of the trial, providing a picture of the baseline firing rate of the neuron. The graph then shows changes in firing rate as the stimulus is presented and the animal responds. Each line of a raster plot represents a single trial, and the action potentials are marked as ticks in the column. To give a sense of the average response of the neuron over the course of a trial, the data are summed and presented as a bar graph known as a peristimulus histogram. Ahistogram allows scientists to visualize the rate and timing of neuronal spike discharges in relation to an external stimulus or event.

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FIGURE 1 Graphing the data from single-cell recording experiments. Raster plots show the timing of action potentials. It can be called a spike raster, raster plot, or raster graph. Here is a raster plot of a face selective cell during forty different trials presenting either a threatening face (a) or a non face stimulus (c). Stimulus onset is marked by the vertical red line. The trials are plotted on the y-axis and time is plotted on the x-axis. Each dot in the raster plot marks the time of occurrence of a single AP spike. (b) and (d) are histograms.

changes are made against a backdrop of activity, given that neurons are constantly firing even in the absence of stimulation or movement. This baseline activity varies widely from one brain area to another. For example, some cells within the basal ganglia have spontaneous firing rates of over 100 spikes per second, whereas cells in another basal ganglia region have a baseline rate of only 1 spike per second. Further confounding the analysis of the experimental measurements, these spontaneous firing levels fluctuate. Single-cell recording has been used in almost all regions of the brain across a wide range of nonhuman species. For sensory neurons, the experimenter might manipulate the input by changing the type of stimulus presented to the animal. For motor neurons, output recordings can be made as the animal performs a task or moves about. Some significant advances in neurophysiology have come about recently as researchers probe higher brain centers to examine changes in cellular activity related to goals, emotions, and rewards. In a typical experiment, recordings are obtained from a series of cells in a targeted area of interest. Thus a functional map can describe similarities and differences between neurons in a specified cortical region. One area

where the single-cell method has been used extensively is the study of the visual system of primates. In a typical experiment, the researcher targets the electrode to a cortical area that contains cells thought to respond to visual stimulation. Once a cell has been identified, the researcher tries to characterize its response properties. A single cell is not responsive to all visual stimuli. A number of stimulus parameters might correlate with the variation in the cell’s firing rate; examples include the shape of the stimulus, its color, and whether it is moving (see Chapter 5). An important factor is the location of the stimulus. As Figure 3.19 shows, all visually sensitive cells respond to stimuli in only a limited region of space. This region of space is referred to as that cell’s receptive field. For example, some neurons respond when the stimulus is located in the lower left portion of the visible field. For other neurons, the stimulus may have to be in the upper right (Figure 3.19b). Neighboring cells have at least partially overlapping receptive fields. As a region of visually responsive cells is traversed, there is an orderly relation between the receptive-field properties of these cells and the external

Methods for the Study of Neural Function | 97 Electrode system Receptive field

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FIGURE 3.19 Electrophysiological methods are used to identify the response characteristics of cells in the visual cortex. (a) While the activity of a single cell is monitored, the monkey is required to maintain fixation, and stimuli are presented at various positions in its field of view. (b) The vertical lines to the right of each stimulus correspond to individual action potentials. The cell fires vigorously when the stimulus is presented in the upper right quadrant, thus defining the upper right as the receptive field for this cell.

world. External space is represented in a continuous manner across the cortical surface: Neighboring cells have receptive fields of neighboring regions of external space. As such, cells form a topographic representation, an orderly mapping between an external dimension such as spatial location and the neural representation of that dimension. In vision, topographic representations are referred to as retinotopic. Cell activity within a retinotopic map correlates with the location of the stimulus (Figure 3.20a,b). There are other types of topographic maps. In Chapter 2, we reviewed the motor and somatosensory maps along the central sulcus that provide topographic representations of the body surface. In a similar sense, auditory areas in the subcortex and cortex contain tonotopic maps, in which the physical dimension reflected in neural organization is the sound frequency of a stimulus. With a tonotopic map, some cells are maximally activated by a 1000-Hz tone and others by a 4000-Hz tone (Figure 3.20c). In addition, neighboring cells tend to be tuned to similar frequencies. Thus, sound frequencies are reflected in cells that are activated upon the presentation of a sound. Tonotopic maps are sometimes referred to as cochleotopic because the cochlea, the sensory apparatus in the ear, contains hair cells tuned to distinct regions of the auditory spectrum. When the single-cell method was first introduced, neuroscientists had high hopes that the mysteries of brain function would finally be solved. All they needed was a catalog of contributions by different cells. Yet it soon became clear that, with neurons, the aggregate behavior of cells might be more than just the sum of its parts. The function of an area might be better understood by identifying the correlations in the firing patterns of groups of neurons rather than identifying the response properties of each individual neuron. This idea has inspired single-cell physiologists to develop new techniques that allow recordings to be made in many neurons simultaneously— what is called multiunit recording. Bruce McNaughton and colleagues at the University of Arizona studied how the rat hippocampus represents spatial information by simultaneously recording from 150 cells (Wilson & McNaughton, 1994). By looking at the pattern of activity over the group of neurons, the researchers were able to show how the rat coded spatial and episodic information differently. Today, it is common to record from over 400 cells simultaneously (Lebedev & Nicolelis, 2006). As we will see in Chapter 8, multiunit recordings from motor areas of the brain are now being used to allow animals to control artificial limbs just by thinking about movement. This dramatic medical advance may change the way rehabilitation programs are designed for paraplegics. For example, multiunit recordings can be obtained while people think about actions they would like

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Secondary auditory cortex FIGURE 3.20 Topographic maps of the visual and auditory cortex. In the visual cortex, the receptive fields of the cells define a retinotopic map. While viewing the stimulus (a), a monkey was injected with a radioactive agent. (b) Metabolically active cells in the visual cortex absorb the agent, revealing how the topography of the retina is preserved across the striate cortex. (c)In the auditory cortex, the frequency-tuning properties of the cells define a tonotopic map. Topographic maps are also seen in the somatosensory and motor cortex.

to perform, and this information can be analyzed by computers to control robotic or artificial limbs.

Single-Cell Recordings inHumans Single-cell recordings from human brains are rare. When surgical procedures are required to treat cases of epilepsy or to remove a tumor, however, intracranial electrodes may be inserted as part of the procedure to localize the abnormality in preparation of the surgical resection. In epilepsy, the electrodes are commonly placed in the medial temporal lobe (MTL), where the focus of generalized seizures is most frequent. Many patients with implanted electrodes have given generously of their time for research purposes, engaging in experimental tasks so that researchers can obtain neurophysiological recordings in humans. Itzhak Fried and his colleagues have found that MTL neurons in humans can respond selectively to specific familiar images. For instance, in one patient a single neuron in the left posterior hippocampus was activated

when presented with different views of the actress Jennifer Aniston but not when presented with images of other well-known known people or places (Quiroga et al., 2005). Another neuron showed an increase in activation when the person viewed images of Halle Berry or read her printed name (Figure 3.21). This neuron corresponds to what we might think of as a conceptual representation, one that is not tied to a particular sensory modality (e.g., vision). Consistent with this idea, cells like these are also activated when the person is asked to imagine Jennifer Aniston or Halle Berry, or to think about movies these actresses have performed in (Cerf et al., 2010).

Electroencephalography Although the electrical potential produced by a single neuron is minute, when populations of neurons are active together, they produce electrical potentials large enough to be measured by non-invasive electrodes that have been placed on the scalp, a method known

Methods for the Study of Neural Function | 99

FIGURE 3.21 The Halle Berry neuron? Recordings were made from a single neuron in the hippocampus of a patient with epilepsy. The cell activity to each picture is shown in the histograms, with the dotted lines indicating the window within which the stimulus was presented. This cell showed prominent activity to Halle Berry stimuli, including photos of her, photos of her as Catwoman, and even her name.

as electroencephalography (EEG). These surface electrodes, usually 20 to 256 of them embedded in an elastic cap, are much bigger than those used for singlecell recordings (Figure 3.22). The electrical potential can be recorded at the scalp because the tissues of the brain, skull, and scalp passively conduct the electrical currents produced by synaptic activity. The fluctuating voltage at each electrode is compared to the voltage at a reference electrode, which is usually located on the mastoid bone at the base of the skull. The recording from each electrode reflects the electrical activity of the underlying brain region. The record of the signals is referred to as an electroencephalogram. EEG yields a continuous recording of overall brain activity. Because we have come to understand that predictable EEG signatures are associated with different behavioral states, it has proved to have many important clinical applications (Figure 3.23). In deep sleep, for example, the EEG is characterized by slow, high-amplitude

oscillations, presumably resulting from rhythmic changes in the activity states of large groups of neurons. In other phases of sleep and in various wakeful states, the pattern changes, but always in a predictable manner. Because normal EEG patterns are well established and consistent among individuals, EEG recordings can be used

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FIGURE 3.23 EEG profiles obtained during various states of consciousness. Recorded from the scalp, the electrical potential exhibits a waveform with time on the x-axis and voltage on the y-axis. Over time, the waveform oscillates between a positive and negative voltage. Very slow oscillations dominate in deep sleep, or what is called the delta wave. When awake, the oscillations occur much faster when the person is relaxed (alpha) or reflect a combination of many components when the person is excited.

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ERP Recordings ERP graphs show the average of EEG waves time-locked to specific events such as the onset of a stimulus or response. Time is plotted on the x-axis and voltage on the y-axis. The ERP is composed of a series of waves with either positive or negative polarities (see Figure 3.24 for an example). The components of the waveform are named according to its polarity, N for negative and P for positive, and the time the wave appeared after stimulus onset. Thus, a wave tagged N100 is a negative wave that appeared 100 milliseconds after a stimulus. Unfortunately, there are some idiosyncrasies in the literature (see Figure 3.25). Some components are labeled to reflect their order of appearance. Thus, N1 can refer to the first negative peak. Care must also be used when looking at the wave polarity, because some researchers plot negative in the upward direction and others in the downward direction. Some components of the ERP have been associated with psychological processes: ■

After a stimulus, the earliest components are connected with sensory processing and occur within

to detect abnormalities in brain function. For example, EEG provides valuable information in the assessment and treatment of epilepsy (see Figure 3.10b).

Event-Related Potential EEG reveals little about cognitive processes, because the recording tends to reflect the brain’s global electrical activity. Another approach used by many cognitive neuroscientists focuses on how brain activity is modulated in response to a particular task. The method requires extracting an evoked response from the global EEG signal. EEG

the first 100 ms. This trait has made them an important tool for clinicians evaluating sensory systems. Waves that occur 100 ms after the stimulus presentation are no longer solely derived from sensory processing, but are modulated by attention. The N100 and P100 waves are associated with selectiveattention. The N200 wave is known as the mismatch negativity component. It is found when a stimulus is physically deviant from the preceding stimuli, such as when a G tone is heard after a series of C tones. The P300 wave is seen when an attended stimulus is presented, especially if the stimulus is relatively rare. The N400 component is observed when a stimulus is unexpected. It differs from the N200 in that the surprise event here might be a violation of semantics (e.g., “The cow jumped over the banana”), rather than a physical change.

The logic of this approach is as follows: EEG traces recorded from a series of trials are averaged together by aligning them relative to an external event, such as the onset of a stimulus or response. This alignment eliminates variations in the brain’s electrical activity that are unrelated to the events of interest. The evoked response, or event-related potential (ERP), is a tiny signal embedded in the ongoing EEG that was triggered by the stimulus. By averaging the traces, investigators can extract this signal, which reflects neural activity that is specifically related to the sensory, motor, or cognitive event that evoked it— hence the name event-related potential (Figure 3.24).

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FIGURE 3.24 Recording an ERP. The relatively small electrical responses to specific events can be observed only if the EEG traces are averaged over a series of trials. The large background oscillations of the EEG trace make it impossible to detect the evoked response to the sensory stimulus from a single trial. Averaging across tens or hundreds of trials, however, removes the background EEG, leaving the event-related potential (ERP). Note the difference in scale between the EEG and ERP waveforms.

Methods for the Study of Neural Function | 101 ERPs provide an important tool for clinicians. For example, the visual evoked potential can be useful in diagnosing multiple sclerosis, a disorder that leads to demyelination. When demyelination occurs in the optic nerve, the electrical signal does not travel as quickly, and the early peaks of the visual evoked response are delayed in their time of appearance. Similarly, in the auditory system, tumors that compromise hearing by compressing or damaging auditory processing areas can be localized by the use of auditory evoked potentials (AEPs) because characteristic wave peaks and troughs in the AEP are known to arise from neuronal activity in specific anatomic areas of the ascending auditory system. The earliest of these AEP waves indicates activity in the auditory nerve, occurring within just a few milliseconds of the sound. Within the first 20 to 30 ms after the sound, a series of AEP waves indicates, in sequence, neural firing in the brainstem, then midbrain, then thalamus, and finally the cortex (Figure 3.25).

Primary auditory cortex

Note that these localization claims are based on indirect methods, because the electrical recordings are actually made on the surface of the scalp. For early components related to the transmission of signals along the sensory pathways, the neural generators are inferred from the findings of other studies that use direct recording techniques as well as considerations of the time required for neural signals to travel. This approach is not possible when researchers look at evoked responses generated by cortical structures. The auditory cortex relays its message to many cortical areas, which all contribute to the measured evoked response, making it much harder to localize these components. ERPs are thus better suited to addressing questions about the time course of cognition rather than to localizing the brain structures that produce the electrical events. For example, as we will see in Chapter 7, evoked responses can tell us when attention affects how a stimulus is processed. ERPs also provide physiological indices of when a person decides to respond or when an error is detected.

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FIGURE 3.25 Measuring auditory evoked potentials. The evoked potential shows a series of positive (P) and negative (N) peaks at predictable points in time. In this auditory evoked potential, the early peaks are invariant and have been linked to neural activity in specific brain structures. Later peaks are task dependent, and localization of their source has been a subject of much investigation and debate.

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Time (ms) FIGURE 3.26 Time-frequency analysis plot. Stimulus is presented at time 0. The color represents “power,” or the activity (as indicated at the bar on the right, where blue is the lowest activity and red is the highest) of a particular frequency at various times both before and after the stimulus is presented. Alpha rhythm (8–12Hz; circled lower left) is strong prior to the onset of a stimulus. Following the stimulus, there is a shift in the EEG waveform with increasing power at lower frequencies, as well as higher frequencies (not shown).

Lately, researchers also have been interested in the event-related oscillatory activity in the EEG signal. The waves of the EEG signal represent a number of rhythms, reflecting the synchronized and oscillatory activity of groups of neurons. Presumably, recognizing something requires not only that individual neurons fire but also that they fire in a coherent manner. This coherent firing is what produces the rhythms of the brain. The rhythms are defined by the frequency of the oscillations; thus, alpha refers to frequencies around 10 Hz, or 10 times per second (Figure 3.26). Time-frequency analysis refers to the fact that the amplitude (i.e., power) of a wave in different frequency regions varies over the course of processing. Thus time-frequency analysis is a way to characterize two-dimensional signals that vary in time. Just as with ERP, activity is linked to an event and measured over time; but the strength of the activity in different EEG frequencies is measured, rather than summing the signal of all of the activity.

Magnetoencephalography A technique related to the ERP method is magnetoencephalography, or MEG. The electrical current associated with synaptic activity produces small magnetic fields that are perpendicular to the current. As with EEG, MEG traces can be recorded and averaged over a series of trials to obtain event-related fields (ERFs). MEG provides the same temporal resolution as with ERPs, but it can be used more reliably to localize the source of the signal. Unlike electrical signals, magnetic fields are not distorted as they pass through the brain, skull, and scalp. Modeling techniques, similar to those used in EEG, are necessary to

localize the source of the electrical activity. With MEG data, however, the solutions are more accurate. Indeed, the reliability of spatial resolution with MEG has made it a useful tool in neurosurgery (Figure 3.27), where it is employed to identify the focus of epileptic seizures and to locate tumors in areas that present a surgical dilemma. For example, learning that a tumor extends into the motor cortex of the precentral sulcus, a surgeon may avoid or delay a procedure if it is likely to damage motor cortex and leave the person with partial paralysis. MEG has two drawbacks. First, it is able to detect current flow only if that flow is oriented parallel to the surface of the skull. Most cortical MEG signals are produced by intracellular current flowing within the apical dendrites of pyramidal neurons (see Chapter 2). For this reason, the neurons that can be recorded with MEG tend to be located within sulci, where the long axis of each apical dendrite tends to be oriented parallel to the skull surface. Another problem with MEG stems from the fact that the magnetic fields generated by the brain are extremely weak. To be effective, the MEG device requires a room that is magnetically shielded from all external magnetic fields, including the Earth’s magnetic field. To detect the brain’s weak magnetic fields, the sensors, known as superconducting quantum interference devices (SQUIDS), are encased in large, liquid-helium-containing cylinders that keep them colder than 4 degrees Kelvin.

Electrocortogram An electrocortogram (ECoG) is similar to an EEG, except that the electrodes are placed directly on the

Methods for the Study of Neural Function | 103

MEG Analysis of a response to a tone Subject Undergoing MEG Procedure

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FIGURE 3.27 Magnetoencephalography as a noninvasive presurgical mapping procedure. (a) This MRI shows a large tumor in the vicinity of the central sulcus. (b) Device used to record MEG showing location of the SQUIDS. (c) These event-related fields (ERFs) were produced following repeated tactile stimulation of the index finger. Each trace shows the magnetic signal recorded from an array of detectors placed over the scalp. (d) Inverse modeling showed that the dipole (indicated by LD2) producing the surface recordings in part (a) was anterior to the lesion. (e) This three-dimensional reconstruction shows stimulation of the fingers and toes on the left side of the body in red and the tumor outlined in green.

surface of the brain, either outside the dura or beneath it. Thus, ECoG is appropriate only for people who are undergoing neurosurgical treatment. The ECoG recordings provide useful clinical information, allowing the surgical team to monitor brain activity to identify the location and frequency of abnormal brain activity. Since the implants are left in place for a week, there is time to conduct experiments in which the person performs some sort of cognitive task. ECoG electrodes measure electrical signals before they pass through the scalp and skull. Thus, there is far less signal distortion compared

with EEG. This much cleaner signal results in excellent spatial and temporal resolution. The electrodes can also be used to stimulate the brain and to map and localize cortical and subcortical neurologic functions, such as motor or language function. Combining seizure data with the knowledge of what structures will be affected by surgery permits a risk–benefit profile of the surgery to be established. ECoG is able to detect high-frequency brain activity, information that is attenuated or distorted in scalp EEG recordings. The experimental question in ECoG studies,

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FIGURE 3.28 Structural MRI renderings with electrode locations for four study participants. Structural MRI images to indicate position of electrode grid on four patients. Electrodes that exhibited an increase in high frequency (gamma) power following the presentation of verbs are shown in green. Red circles indicate electrodes in which the increase in gamma was also observed when the verb condition was compared to acoustically matched nonwords. Verb processing is distributed across cortical areas in the superior temporal cortex and frontal lobe.

however, is frequently dictated by the location of the ECoG grid. For example, Robert Knight and his colleagues (2007) studied patients who had ECoG grids that spanned temporal and frontal regions of the left hemisphere. They monitored the electrical response when people processed words. By examining the signal changes across several frequency bands, the researchers could depict the successive recruitment of different neural regions (Figure 3.28). Shortly (100 ms) after the stimulus was presented, the signal for very high-frequency components of the ECoG signal (high gamma range) increased over temporal cortex. Later on, the activity change was observed over frontal cortex. By comparing trials in which the stimuli were words and trials in which the stimuli were nonsense sounds, the researchers could determine the time course and neural regions involved in distinguishing speech from nonspeech.

TAKE-HOME MESSAGES ■

Single-cell recording allows neurophysiologists to record from individual neurons in the animal brain in order to understand how increases and decreases in the activity of neurons correlate with stimulation of one of the senses or behavior.

An event-related potential (ERP) is a change in electrical activity that is time-locked to specific events, such as the presentation of a stimulus or the onset of a response. When the events are repeated many times, the relatively small changes in neural activity triggered by these events can be observed by averaging of the EEG signals. In this manner, the background fluctuations in the EEG signal are removed, revealing the event-related signal with great temporal resolution.

Electrocortogram (ECoG) is similar to an EEG, except that the electrodes are placed directly on the surface ofthe brain.

Magnetoencephalography (MEG) measures the magnetic signals generated by the brain. The electrical activity of neurons also produces small magnetic fields, which can be measured by sensitive magnetic detectors placed along the scalp. MEG can be used in an event-related manner similar to ERPs, with similar temporal resolution. The spatial resolution can be superior because magnetic signals are minimally distorted by organic tissue such as the brain or skull.

With multiunit recording, the activity of hundreds of cells can be recorded at the same time.

The Marriage of Function and Structure: Neuroimaging

Electroencephalography (EEG) measures the electrical activity of the brain. The EEG signal includes endogenous changes in electrical activity as well as changes triggered by specific events (e.g., stimuli or movements).

The most exciting advances for cognitive neuroscience have been provided by imaging techniques that allow researchers to continuously measure physiological

The Marriage of Function and Structure: Neuroimaging | 105 on need. When a brain area is active, more oxygen and glucose are provided by increasing the blood flow to that active region, at the expense of other parts of the brain.

changes in the human brain that vary as a function of a person’s perceptions, thoughts, feelings, and actions (Raichle, 1994). The most prominent of these neuroimaging methods are positron emission tomography, commonly referred to as PET, and functional magnetic resonance imaging, or fMRI. These methods detect changes in metabolism or blood flow in the brain while the participant is engaged in cognitive tasks. They enable researchers to identify brain regions that are activated during these tasks and to test hypotheses about functional anatomy. Unlike EEG and MEG, PET and fMRI do not directly measure neural events. Rather, they measure metabolic changes correlated with neural activity. Like all cells of the human body, neurons require oxygen and glucose to generate the energy to sustain their cellular integrity and perform their specialized functions. As with all other parts of the body, oxygen and glucose are distributed to the brain by the circulatory system. The brain is a metabolically demanding organ. The central nervous system uses approximately 20 % of all the oxygen that we breathe. Yet the amount of blood supplied to the brain varies only a little between times when the brain is most active and when it is quiescent. (Perhaps this is so because what we regard as active and inactive in relation to behavior does not correlate with active and quiescent in the context of neural activity.) Thus, the brain must regulate how much or how fast blood flows to different regions depending

Positron Emission Tomography PET activation studies measure local variations in cerebral blood flow that are correlated with mental activity (Figure 3.29). A radioactive substance is introduced into the bloodstream. The radiation emitted from this “tracer” is monitored by the PET instrument. Specifically, the radioactive isotopes within the injected substance rapidly decay by emitting a positron from their atomic nuclei. When a positron collides with an electron, two photons, or gamma rays, are created. The two photons move in opposite directions at the speed of light, passing unimpeded through brain tissue, skull, and scalp. The PET scanner—essentially a gamma ray detector—determines where the collision took place. Because these tracers are in the blood, a reconstructed image shows the distribution of blood flow: Where there is more blood flow, there will be more radiation. The most common isotope used in cognitive studies is 15O, an unstable form of oxygen with a half-life of 123 seconds. This isotope, in the form of water (H215O), is injected into the bloodstream while a person is engaged in a cognitive task. Although all areas of the body will use some of the radioactive oxygen, the fundamental

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FIGURE 3.29 Positron emission tomography. (a) PET scanning allows metabolic activity to be measured in the human brain. (b)In the most common form of PET, water labeled with radioactive oxygen, 15O, is injected into the participant. As positrons break off from this unstable isotope, they collide with electrons. A by-product of this collision is the generation of two gamma rays, or photons, that move in opposite directions. The PET scanner measures these photons and calculates their source. Regions of the brain that are most active will increase their demand for oxygen, hence active regions will have a stronger PET signal.

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assumption of PET is that there will be increased blood flow to the brain regions that have heightened neural activity. Thus PET activation studies measure relative activity, not absolute metabolic activity. In a typical PET experiment, the injection of tracer is administered at least twice: during a control condition and during one or more experimental conditions. The results are usually reported as a change in regional cerebral blood flow (rCBF) between the control and experimental conditions. PET scanners are capable of resolving metabolic activity to regions, or voxels, of approximately 5 to 10 mm3. Although this volume includes thousands of neurons, it is sufficient to identify cortical and subcortical areas of enhanced activity. It can even show functional variation within a given cortical area, as the images in Figure 3.30 demonstrate.

PiB: A Recent Addition to the PET Tracer Family Recognizing that PET scanners can measure any radioactive agent, researchers have sought to develop specialized molecules that might serve as biomarkers of particular neurological disorders and pathologies.

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One important result has been the synthesis of PiB, or Pittsburgh Compound B, a radioactive agent developed by Chester Mathis and William Klunk at the University of Pittsburgh when they were looking for new ways to diagnosis and monitor Alzheimer’s disease. Historically, Alzheimer’s has been a clinical diagnosis (and frequently misdiagnosed), because a definitive diagnosis required sectioning brain tissue postmortem to identify the characteristic beta-amyloid plaques and neurofibrillary tangles. A leading hypothesis for the cause of Alzheimer’s disease is that the production of amyloid, a ubiquitous protein in tissue, goes awry and leads to the characteristic plaques. Beta-amyloid plaques in particular appear to be a hallmark of Alzheimer’s disease. Mathis and Klunk set out to find a radioactive compound that would specifically label beta-amyloid. After testing hundreds of compounds, they identified PiB, a protein-specific, carbon11-labeled dye that could be used as a PET tracer (Klunk et al., 2004). PiB binds to beta-amyloid (Figure 3.31), providing physicians with an in vivo assay of the presence of this biomarker. PET scans can now be used to measure beta-amyloid plaques, thus adding a new tool for

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FIGURE 3.30 Measurements of cerebral blood flow using PET to identify brain areas involved in visual perception. (a) Baseline condition: Blood flow when the participant fixated on a central cross. Activity in this baseline condition was subtracted from that in the other conditions in which the participant views a checkerboard surrounding the fixation cross to help participants from moving their eyes. The stimulus ispresented at varying positions, ranging from near the center of vision to the periphery (b–d). Aretinotopic map can be identified in which central vision is represented more inferiorly than peripheral vision. Areas that were more active when the participant was viewing the checkerboard stimulus will have higher counts, reflecting increased blood flow. This subtractive procedure ignores variations in absolute blood flow between the brain’s areas. The difference image identifies areas that show changes in metabolic activity as a function of the experimental manipulation.

The Marriage of Function and Structure: Neuroimaging | 107 Control

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diagnosing Alzheimer’s. What’s more, it can be used to screen people showing very early stages of cognitive impairment, or even people who are asymptomatic, to predict the likelihood of developing Alzheimer’s. Being able to diagnose the disease definitively is a boon to patient treatment—because of the previously substantial risk of misdiagnosis—and to research, as scientists develop new experimental drugs designed either to disrupt the pathological development of plaques or to treat the symptoms of Alzheimer’s.

Functional Magnetic Resonance Imaging As with PET, functional magnetic resonance imaging (fMRI) exploits the fact that local blood flow increases in active parts of the brain. The procedure is essentially identical to the one used in traditional MRI. Radio waves cause the protons in hydrogen atoms to oscillate, and a detector measures local energy fields that are emitted as the protons return to the orientation of the magnetic field created by the MRI machine. With fMRI, however, imaging is focused on the magnetic properties of the deoxygenated form of hemoglobin, deoxyhemoglobin. Deoxygenated hemoglobin is paramagnetic (i.e., weakly magnetic in the presence of a magnetic field), whereas oxygenated hemoglobin is not. The fMRI detectors measure the ratio of oxygenated to deoxygenated hemoglobin; this value is referred to as the blood oxygen level–dependent, or BOLD, effect. Intuitively, it might be expected that the proportion of deoxygenated hemoglobin will be greater in the area surrounding active brain tissue, given the intensive metabolic costs associated with neural function. fMRI results, however, are generally reported as an increase in the ratio of oxygenated to deoxygenated hemoglobin. This change occurs because, as a region of the brain becomes active, the amount of blood being directed to

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that area increases. The neural tissue is unable to absorb all of the excess oxygen. Functional MRI studies measure the time course of this process. Although neural events occur on a timescale measured in milliseconds, changes in blood flow are modulated much more slowly. In Figure 3.32, note that following the presentation of a stimulus (in this case, a visual stimulus), an increase in the BOLD response is observed after a few seconds, peaking 6 to 10 seconds later. Thus, fMRI can be used to obtain an indirect measure of neuronal activity by measuring changes in blood flow. Functional MRI has led to revolutionary changes in cognitive neuroscience. Just over 20 years from when the first neuroimaging study appeared in the early 1990s, fMRI papers now fill the pages of neuroscience journals. Functional MRI offers several advantages over PET. MRI scanners are much less expensive and easier to maintain; fMRI uses no radioactive tracers, so it does not incur the

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FIGURE 3.31 Using PiB to look for signs of Alzheimer’s disease. PiB is a PET dye that binds to beta-amyloid. The dye was injected into a man with moderate symptoms of Alzheimer’s disease (a) and into a cognitively-normal woman (b) of similar age. (a) The patient with Alzheimer’s disease shows significant binding of PiB in the frontal, posterior cingulate, parietal, and temporal cortices, as evidenced by the red, orange, and yellow. (b) The control participant shows no uptake of PiB in herbrain.

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FIGURE 3.32 Functional MRI signal observed from visual cortex in the cat with a 4.7-tesla scanner. The black bar indicates the duration of a visual stimulus. Initially there is a dip in the blood oxygen level–dependent (BOLD) signal, reflecting the depletion of oxygen from the activated cells. Over time, the BOLD signal increases, reflecting the increased hemodynamic response to the activated area. Scanners of this strength are now being used with human participants.

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additional costs, hassles, and hazards associated with handling these materials. Because fMRI does not require the injection of radioactive tracers, the same individual can be tested repeatedly, either in a single session or over multiple sessions. Thus, it becomes possible to perform a complete statistical analysis on the data from a single participant. In addition, the spatial resolution of fMRI is superior to PET, in part because high-resolution anatomical images are obtained (using traditional MRI) while the participant is in the scanner.

Functional MRI studies frequently use either a block design, in which neuronal activation is compared between experimental and control scanning phases (Figure 3.33), or an event-related design. Similar to what we saw before in ERP studies, the term eventrelated refers to the fact that, across experimental trials, the BOLD response will be linked to specific events such as the presentation of a stimulus or the onset of a movement. Although metabolic changes to any single event are likely to be hard to detect among background fluctuations in the brain’s hemodynamic response, a clear signal can be obtained by averaging over repetitions of these events. Event-related fMRI improves the experimental design because experimental and control trials can be presented randomly. Researchers using this approach can be more confident that the participants are in a similar attentional state during both types of trials, which increases the likelihood that the observed differences reflect the hypothesized processing demands rather than more generic factors, such as a change in overall arousal. Although a block design experiment is better able to detect small effects, researchers can use a greater range of experimental setups with event-related design; indeed, some questions can be studied only by using event-related fMRI (Figure 3.34). A powerful feature of event-related fMRI is that the experimenter can choose to combine the data in many different ways after scanning is completed. For example, consider memory failure. Most of us have

Block Design Versus Event-Related Design Experiments Functional MRI and PET differ in their temporal resolution, which has ramifications for study designs. PET imaging requires sufficient time to detect enough radiation to create images of adequate quality. The participant must be engaged continually in a single given experimental task for at least 40 s, and metabolic activity is averaged over this interval. Because of this time requirement, block design experiments must be used with PET. In a block design experiment, the recorded neural activity is integrated over a “block” of time during which the participant either is presented a stimulus or performs a task. The recorded activity pattern is then compared to other blocks that have been recorded while doing the same task or stimulus, a different task or stimulus, or nothing at all. Because of the extended time requirement, the specificity of correlating activation patterns with a specific cognitive process suffers.

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FIGURE 3.33 Functional MRI measures time-dependent fluctuations in oxygenation with good spatial resolution. The participant in this experiment viewed a field of randomly positioned white dots on a black background. The dots would either remain stationary or move along the radial axis. The 40-s intervals of stimulation (shaded background) alternated with 40-s intervals during which the screen was blank (white background). (a) Measurements from primary visual cortex (V1) showed consistent increases during the stimulation intervals compared to the blank intervals. (b) In area MT, a visual region associated with motion perception (see Chapter 5), the increase was observed only when the dots were moving.

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experienced the frustration of being introduced to someone at a party and then being unable to remember the person’s name just 2 minutes later. Is this because a Block design we failed to listen carefully during the original intro0 duction, so the information never really entered memory? Or did the information enter our memory stores 0 16 32 48 64 80 Time (s) but, after 2 minutes of distraction, we were unable to access the information? The former would constitute a problem with memory encoding; the latter would b Event-related reflect a problem with memory retrieval. Distinguishing between these two possibilities has been difficult, 0 Stimulus presentations BOLD responses as evidenced by the thousands of articles on this topic 16 32 48 64 80 0 Time (s) that have appeared in cognitive psychology journals over the past 100 years. FIGURE 3.34 Block design versus event-related design. Anthony Wagner and his Posterior LIFG colleagues at Harvard University 4 used event-related fMRI to take 3 a fresh look at the question of memory encoding versus reRemembered 2 trieval (Wagner et al., 1998). 1 They obtained fMRI scans while participants were studying a list 0 Forgotten of words, where one word ap–1 peared every 2 seconds. About 0 2 4 6 8 10 12 14 20 minutes after completing the Time (s) a scanning session, the particiParahippocampal/fusiform gyri pants were given a recognition 4 memory test. On average, the 3 Remembered participants correctly recognized 88 % of the words studied 2 during the scanning session. The 1 researchers then separated the Forgotten 0 trials on the basis of whether a word had been remembered or –1 2 4 6 8 10 12 14 forgotten. If the memory failure 0 Time (s) was due to retrieval difficulties, b no differences should be detectRight motor Left visual 4 4 ed in the fMRI response to these cortex cortex 3 two trials, since the scans were 3 obtained only while the partici2 2 pants were reading the words. 1 1 If the memory failure was due 0 to poor encoding, however, the 0 –1 researchers would expect to see –1 –2 a different fMRI pattern follow2 4 6 8 10 12 14 ing presentation of the words 0 2 4 6 8 10 12 14 0 Time (s) Time (s) c that were later remembered FIGURE 3.35 Event-related fMRI study showing memory failure as a problem of encoding. compared to those that were Both the left inferior frontal gyrus (LIFG) (a) and the parahippocampal region (b) in the left forgotten. The results clearly hemisphere exhibit greater activity during encoding for words that are subsequently rememfavored the encoding-failure bered compared to those that are forgotten. (A = parahippocampal region; B = fusiform gyrus.) hypothesis (Figure 3.35). The (c)Activity over the left visual cortex and right motor cortex is identical following words that BOLD signal recorded from two subsequently are either remembered or forgotten. These results demonstrate that the memory areas, the prefrontal cortex and effect is specific to the frontal and hippocampal regions.

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the hippocampus, was stronger following the presentation of words that were later remembered. (As we’ll see in Chapter 9, these two areas of the brain play a critical role in memory formation.) The block design method could not be used in a study like this, because the signal is averaged over all of the events within each scanning phase.

Limitations of PET and fMRI It is important to understand the limitations of imaging techniques such as PET and fMRI. First, PET and fMRI have poor temporal resolution compared with single-cell recordings or ERPs. PET is constrained by the decay rate of the radioactive agent (on the order of minutes), and fMRI is dependent on the hemodynamic changes (on the order of seconds) that underlie the BOLD response. A complete picture of the physiology and anatomy of cognition usually requires integrating results obtained in ERP studies with those obtained in fMRI studies. A second difficulty arises when interpreting the data from a PET or fMRI study. The data sets from an imaging study are massive, and often the comparison of experimental and control conditions produces many differences. This should be no surprise, given what we know about the distributed nature of brain function. For example, asking someone to generate a verb associated with a noun (experimental task) likely requires many more cognitive operations than just saying the noun (control task). As such, it is difficult to make inferences about each area’s functional contribution from neuroimaging data. Correlation does not imply causation. For example, an area may be activated during a task but not play a critical role in performance of the task. The BOLD signal is primarily driven by neuronal input rather than output (Logothetis et al., 2001); as such, an area showing increased activation may be downstream from brain areas that provide the critical computations. Rather than focus on local changes in activity, the data from an fMRI study can be used to ask whether the activation changes in one brain area are correlated with activation changes in another brain area—that is, to look at what is called functional connectivity (Sun et al., 2004). In this manner, fMRI data can be used to describe networks associated with particular cognitive operations and the relationships among nodes within those networks. This process is discussed next.

TAKE-HOME MESSAGES ■

Positron emission tomography (PET) measures metabolic activity in the brain by monitoring the distribution of a radioactive tracer. The PET scanner measures the

photons that are produced during decay of the tracer. A popular tracer is 15O because it decays rapidly and the distribution of oxygen increases to neural regions that are active. ■

Pittsburgh Compound B (PiB) is a tracer that binds to beta-amyloid and is used as an in vivo assay of the presence of this biomarker for Alzheimer’s disease.

Functional magnetic resonance imaging (fMRI) uses MRI to measure changes in the oxygen content of the blood (hemodynamic response). These changes are assumed to be correlated with local changes in neuronal activity.

Brain Graphs Whether counting neurons or measuring physiological and metabolic activity, it is clear that the brain is made up of networks of overwhelmingly complicated connections. Just as a picture is worth a thousand words, a graph helps illuminate the complex communication systems in the brain. Graphs are a tool for understanding connections and patterns of information flow. Methods originally developed in computer science to study problems like air traffic communication are now being adopted by neuroscientists to develop brain graphs. A brain graph is a visual model of the connections within some part of the nervous system. The model is made up of nodes, which are the neural elements, and edges, which are the connections between neural elements. The geometric relationships of the nodes and edges define the graph and provide a visualization of brain organization. Neuroscientists can construct brain graphs by using the data obtained from just about any neuroimaging method (Figure 3.36). The selected data set will dictate what constitutes the nodes and edges. For instance, the nematode worm, Caenorhabditis elegans, is the only organism for which the entire network of cellular connections have been completely described. Because of its very limited nervous system, a brain graph can be constructed in which each node is a neuron. On the scale of the human brain, however, with its millions of neurons, the nodes and edges represent anatomically or functionally defined units. For instance, the nodes might be clusters of voxels and the edges a representation of nodes that show correlated patterns of activation. In this manner, researchers can differentiate between nodes that act as hubs, sharing links with many neighboring nodes, and nodes that act as connectors, providing links to more distant clusters. Beyond simply showing the edges, a brain graph can also depict the relative strength, or weighting, of the edges. Brain graphs are a valuable way to compare results from experiments using different methods (Bullmore &

Computer Modeling | 111 Bassett, 2011). For instance, graphs based on anatomical measures such as diffusion tensor imaging (DTI) can be compared with graphs based on functional measures such as fMRI. Brain graphs also provide ways to visualize the organizational properties of neural networks. For instance, three studies employing vastly different data sets to produce graphical models have reported similar associations between general intelligence and topological measures of brain network efficiency (van den Heuvel et al., 2009; Bassett et al., 2009; Li et al. 2009). Brain graphs promise to provide a new perspective on neurological and psychiatric disorders. The neurological problems observed in patients with traumatic brain injury (TBI) likely reflect problems in connectivity, rather than restricted damage to specific brain regions. Even when the pathology is relatively restricted, as in stroke, the network properties of the brain are likely disrupted (Catani & ffytche, 2005).

Brain graphs can be used to reveal these changes, providing a bird’s-eye view of the damaged landscape.

TAKE-HOME MESSAGE ■

A brain graph is a visual model of brain organization, and can be defined either with structural or functional data. Because it can be constructed from data obtained through different types of neuroimaging methods, a brain graph is a valuable way to compare results from experiments using different methods.

Computer Modeling

Creating computer models to simulate postulated brain processes is a research method that complements the other methods discussed in this chapter. A simulation is an imitation, a reproduction of behavior in an alternative medium. The simulated cognitive processes are commonly referred to as artificial intelligence—artificial in the sense that they are artifacts, human creations—and intelligent in that the computers perform complex functions. The simulations are designed to mimic behavior and the cognitive processes supporting that behavior. The computer is given input and then must perform internal operations to create a behavior. By observing the behavior, the researcher can assess how well it matches behavior produced by a real mind. Of course, to get the computer to succeed, the modeler must specify how information is represented and transformed within the program. To do this, he or she must generate concrete hypotheses regarding the “mental” operations needed for the machine. As such, computer simulations provide a useful tool FIGURE 3.36 Constructing a human brain network. for testing theories of cogniA brain network can be constructed with either structural or functional imaging data. The data tion. The success and failure of imaging methods such as anatomical MRI or fMRI can be divided into regions of interest. This step various models yields valuable would already be performed by the sensors in EEG and MEG studies. Links between the regions of insight into the strengths and interest can then be calculated, using measures like DTI strength or functional connectivity. From these data, brain networks can be constructed. weaknesses of a theory.

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THE COGNITIVE NEUROSCIENTIST’S TOOLKIT

Analyzing Brain Scans In general, brains all have the same components; but just like fingerprints, no two brains are exactly the same. Brains vary in overall size, in the size and location of gyri, in the size of individual regions, in shape, and in connectivity. As a result, each brain has a unique configuration, and each person solves problems in different ways. This variation presents a problem when trying to compare the structures and functions of one brain with another. One solution is to use mathematical methods to align individual brain images into a common space, building on the assumption that points deep in the cerebral hemispheres have a predictable relationship to the horizontal planes running through the anterior and posterior commissures, two large white matter tracts connecting the two cerebral hemispheres. In 1988, Jean Talairach and Pierre Tournoux published a standardized, three-dimensional, proportional grid system to identify and measure brain components despite their variability (Talairach & Tournoux, 1988). Using the postmortem brain of a 60-year-old French woman, they divided the brain into thousands of small, volume-based units, known as voxels (think of tiny cubes). Each voxel was given a 3-D Talairach coordinate in relation to the anterior commissure, on the x (left or

Computer models are useful because they can be analyzed in detail. In creating a simulation, however, the researcher must specify explicitly how the computer is to represent and process information. This does not mean that a computer’s operation is always completely predictable and that the outcome of a simulation is known in advance. Computer simulations can incorporate random events or be on such a large scale that analytic tools do not reveal the solution. The internal operations, the way information is computed, however, must be known. Computer simulations are especially helpful to cognitive neuroscientists in recognizing problems that the brain must solve to produce coherent behavior. Braitenberg (1984) provided elegant examples of how modeling brings insight to information processing. Imagine observing the two creatures shown in Figure 3.37 as they move about a minimalist world consisting of a single heat source, such as a sun. From the outside, the creatures look identical: They both have two sensors and four wheels. Despite this similarity, their behavior is distinct: One creature moves away from the sun, and the other homes in on it. Why the difference? As outsiders with no access to the internal operations of these creatures, we

right), y (anterioror posterior), and z (superior or inferior) axes. By using these standard anatomical landmarks, researchers can take individual brain images obtained from MRI and PET scans, and morph them onto standard Talairach space as a way to combine information across individuals. There are limitations to this method, however. To fit brains to the standardized atlas, the images must be warped to fit the standard template. The process also requires smoothing, a method that is somewhat equivalent to blurring the image. Smoothing helps compensate for the imperfect alignment, but it can also give a misleading picture of the extent of activation changes among the voxels. The next step in data analysis is a statistical comparison of activation of the thousands of voxels between baseline and experimental conditions. Choosing the proper significance threshold is important. Too high, and you may miss regions that are significant; too low, and you risk including random activations. Functional imaging studies frequently use what is termed “corrected” significance levels, implying that the statistical criteria have been adjusted to account for the many comparisons involved in the analysis.

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FIGURE 3.37 Behavioral differences due to different circuitry. Two very simple vehicles, each equipped with two sensors that excite motors on the rear wheels. The wheel linked to the sensor closest to the sun will turn faster than the other wheel, thus causing the vehicle to turn. Simply changing the wiring scheme from uncrossed to crossed radically alters the behavior of the vehicles. The “coward” will always avoid the source, whereas the “aggressor” will relentlessly pursue it.

Computer Modeling | 113 might conjecture that they have had different experiences and so the same input activates different representations. Perhaps one was burned at an early age and fears the sun, and maybe the other likes the warmth. As their internal wiring reveals, however, the behavioral differences depend on how the creatures are wired. The uncrossed connections make the creature on the left turn away from the sun; the crossed connections force the creature on the right to orient toward it. Thus, the two creatures’ behavioral differences arise from a slight variation in how sensory information is mapped onto motor processes. These creatures are exceedingly simple—and inflexible in their actions. At best, they offer only the crudest model of how an invertebrate might move in response to a phototropic sensor. The point of Braitenberg’s example is not to model a behavior; rather, it represents how a single computational change—from crossed to uncrossed wiring—can yield a major behavioral change. When interpreting such a behavioral difference, we might postulate extensive internal operations and representations. When we look inside Braitenberg’s models, however, we see that there is no difference in how the two models process information, but only a difference in their patterns of connectivity (see the preceding section, on Brain Graphs).

Representations in ComputerModels Computer models differ widely in their representations. Symbolic models include, as we might expect, units that represent symbolic entities. A model for object recognition might have units that represent visual features like corners or volumetric shapes. An alternative architecture that figures prominently in cognitive neuroscience is the neural network. In neural networks, processing is distributed over units whose inputs and outputs represent specific features. For example, they may indicate whether a stimulus contains a visual feature, such as a vertical or a horizontal line. Models can be powerful tools for solving complex problems. Simulations cover the gamut of cognitive processes, including perception, memory, language, and motor control. One of the most appealing aspects of neural networks is that the architecture resembles the nervous system, at least superficially. In these models, processing is distributed across many units, similar to the way that neural structures depend on the activity of many neurons. The contribution of any unit may be small in relation to the system’s total output, but complex behaviors can be generated by the aggregate action of all the units. In addition, the computations in these models are simulated to occur in parallel. The

activation levels of the units in the network can be updated in a relatively continuous and simultaneous manner. Computational models can vary widely in the level of explanation they seek to provide. Some models simulate behavior at the systems level, seeking to show how cognitive operations such as motion perception or skilled movements can be generated from a network of interconnected processing units. In other cases, the simulations operate at a cellular or even molecular level. For example, neural network models have been used to investigate how variation in transmitter uptake is a function of dendrite geometry (Volfovsky et al., 1999). The amount of detail that must be incorporated into the model is dictated largely by the type of question being investigated. Many problems are difficult to evaluate without simulations, either experimentally because the available experimental methods are insufficient, or mathematically because the solutions become too complicated given the many interactions of the processing elements. An appealing aspect of neural network models, especially for people interested in cognitive neuroscience, is that “lesion” techniques demonstrate how a model’s performance changes when its parts are altered. Unlike strictly serial computer models that collapse if a circuit is broken, neural network models degrade gracefully: The model may continue to perform appropriately after some units are removed, because each unit plays only a small part in the processing. Artificial lesioning is thus a fascinating way to test a model’s validity. Initially, a model is constructed to see if it adequately simulates normal behavior. Then “lesions” can be included to see if the breakdown in the model’s performance resembles the behavioral deficits observed in neurological patients.

Models Lead to TestablePredictions The contribution of computer modeling usually goes beyond assessing whether a model succeeds in mimicking a cognitive process. Models can generate novel predictions that can be tested with real brains. An example of the predictive power of computer modeling comes from the work of Szabolcs Kali of the Hungarian Academy of Sciences and Peter Dayan at the University College London (Kali & Dayan, 2004). Their computer models were designed to ask questions about how people store and retrieve information in memory about specific events—what is called episodic memory (see Chapter 9). Observations from the neurosciences suggest that the formation of episodic memories depends critically on the hippocampus and adjacent areas of the medial temporal lobe, whereas the storage of such memories involves

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the neocortex. Kali and Dayan used a computer model to explore a specific question: How is access to stored memories maintained in a system where the neocortical connections are ever changing (see the discussion on cortical plasticity in Chapter 2)? Does the maintenance of memories over time require the reactivation of hippocampal–neocortical connections, or can neocortical representations remain stable despite fluctuations and modifications over time? The model architecture was based on anatomical facts regarding patterns of connectivity between the hippocampus and neocortex (Figure 3.38). The model was then trained on a set of patterns that represented distinct episodic memories. For example, one pattern of activation might correspond to the first time you visited the Pacific Ocean; another pattern, to the lecture in which you first learned about the Stroop effect. Once the model had mastered the memory set by showing that it could correctly recall a full episode when given only partial information, Kali and Dayan tested it on a consolidation task. Could old memories remain after the hippocampus was disconnected from the cortex if cortical units continued to follow their initial learning rules? In essence, this was a test of whether lesions to the hippocampus would disrupt long-term episodic memory. The results indicated that episodic memory became quite impaired

when the hippocampus and cortex were disconnected. Thus the model predicts that hippocampal reactivation is necessary for maintaining even well-consolidated episodic memories. In the model, this maintenance process requires a mechanism that keeps hippocampal and neocortical representations in register with one another, even as the neocortex undergoes subtle changes associated with daily learning. This modeling project was initiated because research on people with lesions of the hippocampus had failed to provide a clear answer about the role of this structure in memory consolidation. The model, based on known principles of neuroanatomy and neurophysiology, could be used to test specific hypotheses concerning one type of memory, episodic memory, and to direct future research. Of course, the goal here is not to make a model that has perfect memory consolidation. Rather, it is to ask how human memory works. The contribution of computer simulations continues to grow in the cognitive neurosciences. The trend in the field is for modeling work to be more constrained by neuroscience. Researchers will replace generic processing units with elements that embody the biophysics of the brain. In a reciprocal manner, computer simulations provide a useful way to develop theory, which may then aid researchers in designing experiments and interpreting results.

Hippocampal cortex

TAKE-HOME MESSAGE ■

Medial temporal neocortex

Computer models are used to simulate neural networks in order to ask questions about cognitive processes and generate predictions that can be tested in future research.

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FIGURE 3.38 Computational model of episodic memory. “Neurons” (●) in neocortical areas A, B, and C are connected in a bidirectional manner to “neurons” in the medial temporal neocortex, which is itself connected bidirectionally to the hippocampus. Areas A, B, and C represent highly processed inputs (e.g., inputs from visual, auditory, or tactile domains). As the model learns, it extracts categories, trends, and correlations from the statistics of the inputs (or patterns of activations) and converts these to weights (w) that correspond to the strengths of the connections. Before learning, the weights might be equal or set to random values. With learning, the weights become adjusted to reflect correlations between the processing units.

As we’ve seen throughout these early chapters, cognitive neuroscience is an interdisciplinary field that draws on ideas and methodologies from cognitive psychology, neurology, the neurosciences, and computer science. Optogenetics is a prime example of how the paradigms and methods from different disciplines have coalesced into a startling new methodology for cognitive neuroscientists and, perhaps soon, for clinicians. The great strength of cognitive neuroscience lies in how diverse methodologies are integrated. Many examples of convergent methods will be evident as you make your way through this book. For example, the interpretation of results from neuroimaging studies

Converging Methods | 115 is frequently guided by other methodologies. Single-cell recording studies of primates can be used to identify regions of interest in an fMRI study of humans. Imaging studies can be used to isolate a component operation that might be linked to a particular brain region based on the performance of patients with injuries to that area. In turn, imaging studies can be used to generate hypotheses that are tested with alternative methodologies. A striking example of this method comes from work asking how people identify objects through touch. An fMRI study on this problem revealed an unexpected result: tactile object recognition led to pronounced activation of the visual cortex, even though the participants’ eyes were shut during the entire experiment (Deibert et al., 1999; Figure 3.39a). One possible reason for visual cortex activation is that the participants identified the objects through touch and then generated visual images of them. Alternatively, the participants might have constructed visual images during tactile exploration and then used the images to identify the objects. A follow-up study with transcranial magnetic stimulation (TMS) was used to pit these hypotheses against one another (Zangaladze et al., 1999). TMS stimulation over the visual cortex impaired tactile object recognition. The disruption was observed only when the TMS pulses were delivered 180 ms after the hand touched the object; no effects were seen with earlier or later stimulation (Figure 3.39b). The results indicate that the visual

representations generated during tactile exploration were essential for inferring object shape from touch. These studies demonstrate how the combination of fMRI and TMS allows investigators to test causal accounts of neural function as well as make inferences about the time course of processing. Obtaining converging evidence from various methodologies enables neuroscientists to make the strongest conclusions possible. One of the most promising methodological developments in cognitive neuroscience is the combined use of imaging, behavioral, and genetic methods. This approach is widely employed in studies of psychiatric conditions known to have a genetic basis. Daniel Weinberger and his colleagues at the National Institutes of Health have proposed that the efficacy of antipsychotic medications in treating schizophrenia varies as a function of how a particular gene is expressed, or what is called a polymorphism (Bertolino et al., 2004; Weickert et al., 2004). In particular, when given an antipsychotic drug, schizophrenics, who have one variant of a gene linked to the release of dopamine in prefrontal cortex, show improved performance on tasks requiring working memory and correlated changes in prefrontal activity. In contrast, schizophrenics with a different variant of the gene did not respond to the drugs. The logic underlying these clinical studies can also be applied to ask how genetic differences within the normal population relate to individual variations in brain

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FIGURE 3.39 Combined use of fMRI and TMS to demonstrate the role of the visual cortex in tactile perception. (a) Functional MRI showing areas of activation in nine people during tactile exploration with the eyes closed. All of the participants show some activation in striate and extrastriate cortex. (b) Accuracy in judging orientation of tactile stimulus that is vibrated against the right index finger. Performance is disrupted when the pulse is applied 180 ms after stimulus onset, but only when the coil is positioned over the left occipital lobe or at a midline point, between the left and right sides of the occipital lobe.

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FIGURE 3.41 Spatial and temporal resolution of the prominent methods used in cognitive neuroscience. Temporal sensitivity, plotted on the x-axis, refers to the timescale over which a particular measurement is obtained. It can range from the millisecond activity of single cells to the behavioral changes observed over years in patients who have had strokes. Spatial sensitivity, plotted on the y-axis, refers to the localization capability of the methods. For example, real-time changes in the membrane potential of isolated dendritic regions can be detected with the patch clamp method, providing excellent temporal and spatial resolution. In contrast, naturally occurring lesions damage large regions of the cortex and are detectable with MRI.

Converging Methods | 117 function and behavior. A common polymorphism in the human brain is related to the gene that codes for monoamine oxidase A (MAOA). Using a large sample of healthy individuals, Weinberger’s group found that the low-expression variant was associated with increased tendency toward violent behavior as well as hyperactivation of the amygdala when the participants viewed emotionally arousing stimuli (Meyer-Lindenberg et al., 2006). Similarly, variation in dopamine-related genes (COMT and DRD4) have been related to differences in risk taking and conflict resolution: Does an individual stick out her neck to explore? How well can an individual make a decision when faced with multiple

choices? Phenotypic differences correlate with the degree of activation in the anterior cingulate, a region associated with the conflict that arises when having to make such choices (Figure 3.40; for a review, see Frank & Fosella, 2011).

TAKE-HOME MESSAGE ■

Powerful insights into the structural and functional underpinnings of cognitive behavior can be gained from experiments that combine methods such as genetic, behavioral, and neuroimaging techniques.

Summary Two goals have guided our overview of cognitive neuroscience methods presented in this chapter. The first was to provide a sense of how various methodologies have come together to form the interdisciplinary field of cognitive neuroscience (Figure 3.41). Practitioners of the neurosciences, cognitive psychology, and neurology differ in the tools they use—and also, often, in the questions they seek to answer. The neurologist may request a CT scan of an aging boxer to determine if the patient’s confusional state is reflected in atrophy of the frontal lobes. The neuroscientist may want a blood sample from the patient to search for metabolic markers indicating a reduction in a transmitter system. The cognitive psychologist may design a reaction time experiment to test whether a component of a decision-making model is selectively impaired. Cognitive neuroscience endeavors to answer all of these questions by taking advantage of the insights that each approach has to offer and using them together. The second goal of this chapter was to introduce methods that we will encounter in subsequent chapters. These chapters focus on content domains such as perception, language, and memory, and on how these tools are being applied to understand the brain and behavior. Each chapter draws on research that uses the diverse methods of cognitive neuroscience. The convergence of results obtained by using different methodologies frequently offers the most complete theories. A single method often cannot bring about a complete understanding of the complex processes of cognition. We have reviewed many methods, but the review is incomplete. Other methods include patch clamp techniques to isolate restricted regions on the neuron, enabling studies of the membrane changes that underlie the flow of neurotransmitters, and

laser surgery can be used to restrict lesions to just a few neurons in simple organisms, providing a means to study specific neural interactions. New methodologies for investigating the relation of the brain and behavior spring to life each year. Neuroscientists are continually refining techniques for measuring and manipulating neural processes at a finer and finer level. Genetic techniques such as knockout procedures have exploded in the past decade, promising to reveal the mechanisms involved in many normal and pathological brain functions. Optogenetics, which uses light to control the activity of neurons and hence to control neural activity and even behavior, has given researchers a new level of control to probe the nervous system. Technological change is also a driving force in our understanding of the human mind. Our current imaging tools are constantly being refined. Each year, more sensitive equipment is developed to measure the electrophysiological signals of the brain or the metabolic correlates of neural activity, and the mathematical tools for analyzing these data are constantly becoming more sophisticated. In addition, entire new classes of imaging techniques are beginning to gain prominence. We began this chapter by pointing out that paradigmatic changes in science are often fueled by technological developments. In a symbiotic way, the maturation of a scientific field such as cognitive neuroscience provides a tremendous impetus for the development of new methods. Obtaining answers to the questions neuroscientists ask is often constrained by the tools available, but such questions promote the development of new research tools. It would be naïve to imagine that current methodologies will become the status quo for the field. We can anticipate the development of new technologies, making this an exciting time to study the brain and behavior.

Key Terms angiography (p. 79) block design experiment (p. 108) blood oxygen level–dependent (BOLD) (p. 107) brain graph (p. 110) brain lesion (p. 79) cerebral vascular accident (79) cognitive psychology (p. 74) computed tomography (CT, CAT) (p. 91) deep-brain stimulation (DBS) (p. 86) degenerative disorder (p. 80) diffusion tensor imaging (DTI) (p. 93)

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double dissociation (p. 84) electrocortogram (ECoG) (p. 102) electroencephalography (EEG) (p. 99) event-related design (p. 108) event-related potential (ERP) (p. 100) functional magnetic resonance imaging (fMRI) (p. 105) knockout procedure (p. 90) magnetic resonance imaging (MRI) (p. 92) magnetoencephalography (MEG) (p. 102)

multiunit recording (p. 97) neural network (p. 113) neurophysiology (p. 95) optogenetics (p. 72) pharmacological studies (p. 87) PiB (p. 106) positron emission tomography (PET) (p. 105) receptive field (p. 96) regional cerebral blood flow (rCBF) (p. 106) retinotopic (p. 97) simulation (p. 111)

single-cell recording (p. 95) single dissociation (p. 84) smoothing (p. 112) Talairach coordinate (p. 112)

time-frequency analysis (p. 102) transcanial direct current stimulation (tDCS) (p. 89)

transcranial magnetic stimulation (TMS) (p. 88) traumatic brain injury (TBI) (p. 81) voxel (p. 106)

Thought Questions 1.

To a large extent, progress in all scientific fields depends on the development of new technologies and methodologies. What technological and methodological developments have advanced the field of cognitive neuroscience?

2.

Cognitive neuroscience is an interdisciplinary field that incorporates aspects of neuroanatomy, neurophysiology, neurology, and cognitive psychology. What do you consider the core feature of each discipline that allows it to contribute to cognitive neuroscience? What are the limits of each discipline in addressing questions related to the brain and mind?

3.

In recent years, functional magnetic resonance imaging (fMRI) has taken the field of cognitive neuroscience by storm. The first studies with this method were reported in the early 1990s; now hundreds of papers are published each month. Provide at least three reasons why this method is so popular. Discuss some of the technical and inferential limitations associated with this method (inferential, meaning limitations in the kinds of questions

the method can answer). Finally, propose an fMRI experiment you would conduct if you were interested in identifying the neural differences between people who like scary movies and those who don’t. Be sure to clearly state the different conditions of the experiment.

4.

Recently, it has been shown that people who performed poorly on spatial reasoning tasks have reduced volume in the parietal lobe. Discuss why caution is advised in assuming that the poor reasoning is caused by the smaller size of the parietal lobe. To provide a stronger test of causality, outline an experiment that involves a training program, describing your conditions, experimental manipulation, outcome measures, and predictions.

5.

Consider how you might study a problem such as color perception by using the multidisciplinary techniques of cognitive neuroscience. Predict the questions that you might ask about this topic, and outline the types of studies that cognitive psychologists, neurophysiologists, and neurologists might consider.

Suggested Reading Chouinard, P. A., & Paus, T. (2010). What have we learned from “perturbing” the human cortical motor system with transcranial magnetic stimulation? Frontiers in Human Neuroscience, 4, Article 173. Frank, M. J., & Fossella, J. A. (2011). Neurogenetics and pharmacology of learning, motivation and cognition. Neuropsychopharmacology, 36, 133–152. Hillyard, S. A. (1993). Electrical and magnetic brain recordings: Contributions to cognitive neuroscience. Current Opinion in Neurobiology, 3, 710–717.

Functional magnetic resonance imaging. Sunderland, MA: Sinauer. Mori, S. (2007). Introduction to diffusion tensor imaging. New York: Elsevier. Posner, M. I., & Raichle, M. E. (1994). Images of mind. New York: Freeman. Rapp, B. (2001). The handbook of cognitive neuropsychology: What deficits reveal about the human mind. Philadelphia: Psychology Press.

Huettel, S., Song, A. W., & McCarthy, G. (2004).

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Practically everybody in New York has half a mind to write a book, and does. Groucho Mar x

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IT WAS 1961, and W.J., a charismatic war veteran, had been suffering two grand mal seizures a week for the previous 10 years. After each seizure subsided, it took him a full day to recover. Although he otherwise appeared perfectly normal, possessed a sharp sense of humor, and charmed all who met him, the seizures were creating havoc in his life. He was willing to try anything that might improve his situation. After critically reviewing the medical literature, a neurosurgery resident, OUTLINE Dr. Joseph Bogen, suggested that W.J. would benefit from a rarely performed Anatomy of the Hemispheres surgical procedure that would sever the corpus callosum, the great fiber tract that connects the right and left cerebral hemispheres. A similar procedure had Splitting the Brain: Cortical been done successfully 20 years earlier on a series of patients in Rochester, Disconnection New York. None of these patients reported ill side effects, and all had imHemispheric Specialization provement in seizure control (Akelaitis, 1941). Psychological studies of these patients before and after their surgeries revealed no differences in their brain The Evolutionary Basis of Hemispheric function or behavior. The concern was that more recent studies of animals that Specialization had undergone split-brain procedures told a different story. Cats, monkeys, Split-Brain Research as a Window into and chimps with callosal sections had dramatically altered brain function. Conscious Experience Nonetheless, W.J. was willing to risk the procedure. He was desperate. In the days following his surgery, it became obvious that the procedure was a great success: W.J. felt no different, and his seizures were completely resolved. His temperament, intellect, and delightful personality remained unchanged. W.J. reported that he felt better than he had in years (Gazzaniga et al., 1962). Because of the results garnered from the animal experiments, it was puzzling that humans apparently suffered no effects from severing the two hemispheres. Ever the gentleman, W.J. submitted to hours of tests, both before and after the surgery, to help solve this mystery. Using a new method, one of the authors (MSG) devised a way to communicate with each hemisphere separately. This method was based on the anatomy of the optic nerve. The nerve from each eye divides in half. Half of the nerve fibers cross and project to the opposite hemisphere, and the other half projects to the ipsilateral hemisphere (Figure 4.1). The parts of both eyes that view the right visual field are processed in the left hemisphere, and the parts that view the left visual field are processed in the right hemisphere. Thus, if all communication is severed between the two halves of the cerebral cortex, then information presented just to the right visual field would feed into the left side of the brain only, and information presented to 121

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t Lef

ld al fie vi s u

Primary visual cortex

the left visual field would be sent to the right side of the brain only, and neither would have access to the other. This type of test had not been tried on the Rochester patients. Before surgery, W.J. could name objects presented to either visual field or objects placed in either of his hands, just like you can. He could understand a command and carry it out with either hand. Would the results be the same after the surgery? Because our speech center is in the left hemisphere, it was expected that W.J. would be able to name items presented to his right visual field and were sent to his left hemisphere. Earlier testing done in Rochester suggested that the corpus callosum was unnecessary for interhemispheric integration of information. If that were true, then W.J. should also be able to report what was flashed to his left visual field and sent to his right hemisphere. First, a picture of a spoon was flashed to his right visual field; he said “spoon.” Then the moment arrived for the critical test. A picture was flashed to his left visual field, and he was asked, “Did you see anything?” To the amazement of all present he replied, “No, I didn’t see anything.” At first it appeared that W.J. was blind to stimuli presented to his left visual field, but it soon became clear that this was not the case. Tweaking the experimental technique, the investigators allowed W.J. to respond by using a Morse code key with his left hand (the right hemisphere controls the left hand) rather than with a verbal response. He responded by pressing the key with his left hand when a light was flashed

FIGURE 4.1 The optic nerve and its pathway to the primary visual cortex.

to his left visual field (hence the right hemisphere), but he stated (his left hemisphere talking) that he saw nothing. The more tests that were done, the more remarkable were the findings: W.J.’s right hemisphere could do things that his left could not do, and vice versa. For example, the two hemispheres were strikingly different in performance on the block design task shown in Figure 4.2. Previously, W.J. had been able to write dictated sentences and carry out any kind of command, such as making a fist or drawing geometric shapes with his right hand. After surgery, though, he could not arrange four red and white blocks in a simple pattern with his right hand. We will see later that the surgery had disconnected specialized systems in the right hemisphere from the motor apparatus in the left hemisphere, which in turn controls the right hand. Even when given as much time as needed, W.J. was unable to perform the task with his right hand, because motor commands specific to the task could not be communicated from the isolated left hemisphere. W.J.’s right hemisphere, however, was a whiz at this type of test. When blocks were presented to his left hand (controlled by his right hemisphere), he quickly and adeptly arranged them into the correct pattern. This simple observation gave birth to the idea that “Mind Left” and “Mind Right” do different things, supporting the idea that the central nervous system is laterally specialized: Each of the two cerebral hemispheres performs processes that the other does not.

Hemispheric Specialization | 123

a

b

FIGURE 4.2 The block design test. The pattern in red on the right is the shape that thepatient is trying to create with the blocks given to him. (a) With his right hand (left hemisphere), he is unable to duplicate the pattern. (b)With his left hand (right hemisphere), he is able to perform the taskcorrectly.

After the first testing session revealed this separation so clearly, investigators arranged to film W.J. carrying out tasks. The scientists knew a young fashion photographer, Baron Wolman, who dabbled in filmmaking (and would later help found Rolling Stone magazine); he was invited to come to a session during which the whole test was carried out again. Wolman could not believe his eyes. During filming, W.J.’s right hand attempted to arrange the blocks, and his left hand kept trying to intervene. Mind Right saw

the problem, knew the solution, and tried to help out just like a good friend. W.J. had to sit on his left hand so that the inadequate but dominant right hand could at least try. For the film’s final scene, they decided to see what would happen if both hands were allowed to arrange the blocks. Here they witnessed the beginning of the idea that Mind Left can have its view of the world with its own desires and aspirations, and Mind Right can have another view. As soon as Mind Right, working through the left hand, began to arrange the blocks correctly, Mind Left would undo the good work. The hands were in competition! The specializations of each hemisphere were different, and growing out of that difference were the behaviors of each half of the brain. These results raised all sorts of questions. Are there two selves? If not, why not? If so, which one is in charge? Do the two sides of the brain routinely compete? Which half decides what gets done and when? Are consciousness and our sense of self located in one half of the brain? And why do split-brain patients generally feel unified and no different even though their two hemispheres do not communicate? Such questions gave birth to the field of human split-brain research. The popular press picked up these findings, and the concept that the “right brain” and “left brain” think differently about the world made its way into the mainstream. This led to the boiled-down notion that the left hemisphere is analytical and logical while the right hemisphere is creative, musical, and intuitive. Many general interest books have been written based on this naïve view: that artists, musicians, and poets mostly use their right hemisphere while lawyers, mathematicians, and engineers mostly use their left hemisphere (Figure 4.3).

FIGURE 4.3 Books perpetuating the common idea that the left brain is analytic and the right brain is creative.

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ANATOMICAL ORIENTATION

The hemispheres of the brain Corpus callosum

Right hemisphere

Posterior commissure

Interhemispheric fissure

Anterior commissure

Left hemisphere

The hemispheres of the brain are distinct yet connected. In the medial view are seen the commissures, the large white matter fiber tracts that connect the hemispheres.

In reality, the science has shown this to be a gross exaggeration of the findings on hemispheric specialization. It turns out that most cognitive processes are redundant and that each hemisphere is capable of carrying out those processes. As we learn in this chapter, however, the hemispheres have some fundamental differences that can help us understand the organization of the cerebral cortex, the evolutionary development and purpose of certain specializations, and the nature of the mind. You should keep in mind, however, that despite all we have learned about hemispheric differences and specializations, the fundamental mystery, first discovered in the surgeries of the 1940s, remains today. That is, patients who undergo split-brain surgery report no change in their mental status, even though their “speaking” left hemisphere has been irretrievably isolated from their right hemisphere and all of the special properties that it may include. These two separate but coexisting brains do not result in split personalities, nor do they fight over control of the body. In short, the individual with the split brain does not feel conflicted. At the end of this chapter, we examine why this is the case and revisit what clues it may offer about our general conscious experience (also see Chapter 14, where these ideas are discussed in more detail).

We will find that research on laterality has provided extensive insights into the organization of the human brain, and that the simplistic left-brain/right-brain claims distort the complex mosaic of mental processes that contribute to cognition. Split-brain studies profoundly demonstrate that the two hemispheres do not represent information in an identical manner. Complementary studies on patients with focal brain lesions underscore the crucial role played by lateralized processes in cognition. This research and recent computational investigations of lateralization and specialization have advanced the field far beyond the popular interpretations of leftbrain/right-brain processes. They provide the scientific basis for future explorations of many fascinating issues concerning cerebral lateralization and specialization. In this chapter, we examine the differences between the right and left cerebral hemispheres using data from studies of split-brain patients as well as those with unilateral brain lesions. We also examine the evolutionary reasons for lateralization of functions, and as noted, the chapter ends with some musing about what split-brain research has to say about the conscious experience. We begin, however, at the beginning: the anatomy and physiology of the two halves and their interconnections.

Anatomy of the Hemispheres | 125 the left hemisphere (Binder & Price, 2001). Regions of the right hemisphere, however, are also engaged, especially for language tasks that require higher-level comprehension (Bookheimer, 2002). Since functional lateralization of language processes clearly exists, can we identify anatomical correlates that account for these lateralized functions?

Anatomy of the Hemispheres Anatomical Correlates of Hemispheric Specialization For centuries, the effects of unilateral brain damage have revealed major functional differences between the two hemispheres. Most dramatic has been the effect of left-hemisphere damage on language functions. In the late 1950s, the dominant role of the left hemisphere in language was confirmed by employing the Wada test, pioneered by Juhn A. Wada and Theodore Rasmussen. This test is often used before elective surgery for the treatment of disorders such as epilepsy to determine in which hemisphere the speech center is located. A patient is given an injection of amobarbital into the carotid artery, producing a rapid and brief anesthesia of the ipsilateral hemisphere (i.e., the hemisphere on the same side as the injection; Figure 4.4). Then the patient is engaged in a series of tests related to language and memory. The Wada test has consistently revealed a strong bias for language lateralization to the left hemisphere, because when the injection is to the left side, the patient’s ability to speak or comprehend speech is disrupted for several minutes. Functional neuroimaging techniques, such as positron emission tomography (PET) and functional magnetic resonance imaging (fMRI), have further confirmed that language processing is preferentially biased to

a

Macroscopic Anatomical Asymmetries The major lobes (occipital, parietal, temporal, and frontal; see Figure 2.00) appear, at least superficially, to be symmetrical, and each half of the cerebral cortex of the human brain is approximately the same size and surface area. The two hemispheres are offset, however. The right protrudes in front, and the left protrudes in back. The right is chubbier (actually has more volume) in the frontal region, and the left is larger posteriorly in the occipital region, frequently nudging the right hemisphere off center and bending the longitudinal fissure between the two hemispheres to the right (Figure 4.5). Anatomists of the nineteenth century observed that the Sylvian fissure (also called the lateral fissure)—the large sulcus that defines the superior border of the temporal lobe—has a more prominent upward curl in the right hemisphere than it does in the left hemisphere, where it is relatively flat. This difference in the shape of the Sylvian fissure between the two cerebral hemispheres is directly related to subsequent reports of size differences in adjacent cortical regions buried within the fissure. At Harvard

b

Left common carotid artery

zz

zz

c

“What is it I gave you?”

z zz

?

zz

“Nothing.”

Amobarbital Dye for angiography

FIGURE 4.4 Methods used in amobarbital (Amytal) testing. (a) Subsequent to angiography, amobarbital is administered to the left hemisphere, anesthetizing the language and speech systems. A spoon is placed in the left hand, and the right hemisphere takes note. (b) When the left hemisphere regains consciousness, the subject is asked what was placed in his left hand, and he responds, “Nothing.” (c) Showing the patient a board with a variety of objects pinned to it reveals that the patient can easily point to the appropriate object, because the right hemisphere directs the left hand during the match-to-sample task.

?

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Left hemisphere

Right hemisphere

Posterior FIGURE 4.5 Anatomical asymmetries between the two cerebral hemispheres. View looking at the inferior surface of the brain; note that the left hemisphere appears on the right side of the image. In this computer-generated reconstruction, the anatomical asymmetries have been exaggerated.

Medical School in the 1960s, Norman Geschwind examined brains obtained postmortem from 100 people known to be right-handed (Geschwind & Levitsky, 1968). After slicing through the lateral fissure, Geschwind measured the temporal lobe’s surface area and discovered that the planum temporale, the cortical area at the center of Wernicke’s area (involved with the understanding of written and spoken language), was larger in the left hemisphere— a pattern found in 65 % of the brains. Of the remaining brains, 11 % had a larger surface area in the right hemisphere and 24 % had no asymmetry. The asymmetry in this region of the temporal lobe may extend to subcortical structures connected to these areas. For example, portions of the thalamus (the lateral posterior nucleus) also tend to be larger on the left. Because these temporal lobe asymmetries seem to be a characteristic of the normally lateralized brain, other investigators have explored whether the asymmetry is absent in individuals with developmental language disorders. Interestingly, MRI studies reveal that the area of the planum temporale is approximately symmetrical in children with dyslexia—a clue that their language difficulties may stem from the lack of a specialized left hemisphere. Interestingly, an MRI study on adults with dyslexia found that the typical medial temporal lobe asymmetries were reversed in dyslexic adults (Casanova et al., 2005).

The asymmetry of the planum temporale is one of the few examples in which an anatomical index is correlated with a well-defined functional asymmetry. The complex functions of language comprehension presumably require more cortical surface. Some questions remain, however, concerning both the validity and the explanatory power of this asymmetry. First, although the left-hemisphere planum temporale is larger in 65 % of right-handers, functional measures indicate that 96 % of right-handers show left-hemisphere language dominance. Second, there is a suggestion that the apparent asymmetries in the planum temporale result from the techniques and criteria used to identify this region. When threedimensional imaging techniques—techniques that take into account asymmetries in curvature patterns of the lateral fissures—are applied, hemispheric asymmetries become negligible. Whether or not this view is correct, the anatomical basis for left-hemisphere dominance in language may not be fully reflected in gross morphology. We also need to examine the neural circuits within these cortical locations.

Microscopic Anatomical Asymmetries By studying the cellular basis of hemispheric specialization, we seek to understand whether differences in neural circuits between the hemispheres might underlie functional asymmetries in tasks such as language. Perhaps specific organizational characteristics of local neuronal networks— such as the number of synaptic connections—may be responsible for the unique functions of different cortical areas. In addition, regions of the brain with greater volume may contain more minicolumns and their connections (Casanova & Tillquist, 2008; see Chapter 2, p. 53). A promising approach has been to look for specializations in cortical circuitry within homotopic areas (meaning areas in corresponding locations in the two hemispheres) of the cerebral hemispheres that are known to be functionally asymmetrical—and what better place to look than in the language area? Differences have been found in the cortical microcircuitry between the two hemispheres in both anterior (Broca’s) and posterior (Wernicke’s) language-associated cortex. We leave the discussion of the function of these areas to Chapter 11; here, we are merely concerned about their structural differences. As we learned in Chapter 2 (p. 38), the cortex is a layered sheet of tightly spaced columns of cells, each comprising a circuit of neurons that is repeated over and over across the cortical surface. From studies of visual cortex, we know that cells in an individual column act together to encode relatively small features of the visual world. Individual columns connect with adjacent and distant columns to form ensembles of neurons that can encode more complex features.

Anatomy of the Hemispheres | 127 In language-associated regions, several types of micro-level asymmetries between the hemispheres have been identified. Some of these asymmetries occur at the level of the individual neurons that make up a single cortical column. For instance, the left hemisphere has greater high-order dendritic branching than that of their homologs in the right hemisphere, which have more loworder dendritic branching (Scheibel et al., 1985). Other asymmetries are found in the relationships between adjacent neuronal columns: Within Wernicke’s area in the left hemisphere, for example, columns are spaced farther from each other, possibly to accommodate additional connectional fibers between the columns. Asymmetries also are found in larger ensembles of more distant cortical columns (Hutsler & Galuske, 2003). Individual cells within a column of the left primary auditory cortex have a tangential dendritic spread that accommodates the greater distance between cell columns, but secondary auditory areas that show the same increase in distance between the columns do not have longer dendrites in the left hemisphere. The cells in these columns contact fewer adjacent cell columns than do those in the right hemisphere. Additional structural differences have been documented in both anterior and posterior language cortex. These asymmetries include cell size differences between the hemispheres, such as those shown in Figure 4.6, and may suggest a greater long-range connectivity in the language-associated regions of the left hemisphere. Asymmetries in connectivity between the two hemispheres have been demonstrated directly by tracing the neuronal connections within posterior languageassociated regions using dyes that diffuse through postmortem tissue. Such dyes show a patchy pattern of

connectivity within these regions of each hemisphere; but within the left hemisphere, these patches are spaced farther apart than those in the right hemisphere (Galuske et al., 2000). What is the functional significance of these various asymmetries within cortical circuitry, and how might these changes specifically alter information processing in the language-dominant hemisphere? Most interpretations of these findings have focused on the relationship between adjacent neurons and adjacent columns, highlighting the fact that differences in both columnar spacing and dendritic tree size would cause cells in the left hemisphere to connect to fewer neurons. This structural specialization might underlie more elaborate and less redundant patterns of connectivity, which in turn might give rise to better separation between local processing streams. Further refinement of this type could also be driving the larger distance between patches in the left hemisphere, since this larger spacing might also imply more refined connections. A thorough understanding of the anatomy and physiology of language-associated cortices could shed considerable light on the cortical mechanisms that facilitate linguistic analysis and production, which we will discuss in Chapter 11. Because cortical areas have a basic underlying organization, documenting cortical locations involved in certain functions should distinguish, in terms of form and variety, between the neural structures common to all regions and the structures critical for a region to carry out particular cognitive functions. These questions hold importance not only for the greater understanding of species-specific adaptations such as language, but also for understanding how evolution may build functional specialization into the framework

Right hemisphere

Left hemisphere

b

a FIGURE 4.6 Layer III pyrimidal cell asymmetry. Visual examination reveals a subtle difference in the sizes of the largest subgroups of layer III pyramidal cells (stained here with acetylthiocholinesterase): in the left hemisphere they are larger (b) compared to the right (a).

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of cortical organization. There are also implications for developmental problems such as dyslexia and autism. For instance, minicolumns in autism are reduced in size and increased in numbers. If changes in these parameters occur early during development, then they would provide for basic alterations in corticocortical connections and information processing (Casanova et al., 2002; 2006).

The Anatomy of Communication The corpus callosum. The left and right cerebral hemispheres are connected by the largest white matter structure in the brain, the corpus callosum. It is made up of approximately 250 million axonal fibers that cross from one side of the brain to the other, facilitating interhemispheric communication. It is located beneath the cortex and runs along the longitudinal fissure. The corpus callosum is divided on a macroscopic level into the anterior portion, called the genu, the middle portion, known as the body, and the posterior portion, called the splenium (Figure 4.7). The neuronal fiber sizes vary across the corpus callosum: Smaller fibers (~0.4 mm) are located anteriorly, fitfully grading to larger fibers (5 mm) located more posteriorly (Aboitiz et al., 1992). The prefrontal and temporoparietal visual areas are connected by the small-diameter, slow-conducting fibers, and the large fibers connect sensorimotor cortices in each hemisphere (Lamantia & Rakic, 1990). As with many parts of the brain, the fiber tracts in the corpus callosum maintain a topographical organization (Zarei et al., 2006).

Body

Splenium

pus callosum Cor

By using the MRI technique known as diffusion tensor imaging (DTI; see Chapter 3), researchers have traced the white fiber tracks from one hemisphere across the corpus callosum to the other hemisphere. The results indicate that the corpus callosum can be partitioned into vertical segments carrying homotopic and heterotopic connections between specific regions of each hemispheric cortex (Hofer & Frahm, 2006). Heterotopic fibers connect different areas between the hemispheres. Figure 4.8 shows a segmentation of the corpus callosum containing fibers projecting into the prefrontal, premotor, primary motor, primary sensory, parietal, temporal, and occipital areas. As can be clearly seen in the figure, almost all of the visual information processed in the occipital, parietal, and temporal cortices is transferred to the opposite hemisphere via the posterior third of the corpus callosum, whereas premotor and supplementary motor information is transferred across a large section of the middle third of the corpus callosum. Many of the callosal projections link homotopic areas (Figure 4.9). For example, regions in the left prefrontal cortex project to homotopic regions in the right prefrontal cortex. Although this pattern holds for most areas of the association cortex, it is not always seen in primary cortex. Callosal projections connecting the two halves of the primary visual cortex link only those areas that represent the most eccentric regions of space; and in both the primary motor and the somatosensory cortices, homotopic callosal projections are sparse (Innocenti et al., 1995). Callosal fibers also connect heterotopic areas (regions with different locations in the two hemispheres). These projections generally mirror the ones found within a hemisphere. For instance, a prefrontal area sending projections to premotor areas in the same hemisphere is also likely to send projections to the analogous premotor area in the contralateral hemisphere. Yet, heterotopic projections are usually Genu less extensive than are projections within the same hemisphere.

FIGURE 4.7 The corpus callosum. A sagittal view of the left hemisphere of a postmortem brain. The corpus callosum is the dense fiber tract located below the folds of the cortex. The anterior portion is the genu, the middle portion is the body, and the posterior portion is the splenium.

The commissures. A much smaller band of fibers connecting the two hemispheres is the anterior commissure. It is about one tenth the size of the corpus callosum, is found inferior to the anterior portion of the corpus callosum, and primarily connects certain regions of the temporal lobes, including the two amygdalae (Figure 4.10). It also contains decussating fibers from the olfactory tract and is part of the neospinothalamic tract for pain. Even smaller is the posterior commissure, which also carries some interhemispheric fibers. It is above the cerebral aqueduct at the junction of the third ventricle

Anatomy of the Hemispheres | 129

a

b

c

(Figure 4.10). It contains fibers that contribute to the papillary light reflex.

Function of the Corpus Callosum The corpus callosum is the primary communication highway between the two cerebral hemispheres. Researchers, of course, are interested in exactly what is being communicated and how. Several functional roles have been proposed for callosal connections. For instance, some researchers point out that in the visual association cortex, receptive fields can span both visual fields. Communication across the callosum enables information from both visual fields to contribute to the activity of these cells.

FIGURE 4.8 3-D reconstruction of transcallosal fiber tracts placed on anatomical reference images. (a) Sagittal view: callosal fiber bundles projecting into the prefrontal lobe (coded in green), premotor and supplementary motor areas (light blue), primary motor cortex (dark blue), primary somatosensory cortex (red), parietal lobe (orange), occipital lobe (yellow), and temporal lobe (violet). (b) Top view. (c)Oblique view.

Indeed, the callosal connections could play a role in synchronizing oscillatory activity in cortical neurons as an object passes through these receptive fields (Figure 4.11). In this view, callosal connections facilitate processing by pooling diverse inputs. Other researchers view callosal function as predominantly inhibitory (See the box “How the Brain Works: Interhemispheric Communication”). If the callosal fibers are inhibitory, they would provide a means for each hemisphere to compete for control of current processing. For example, multiple movements might be activated, all geared to a common goal; later processing would select one of these candidate movements (see Chapter 8). Inhibitory connections across the corpus callosum might be one contributor to this selection process.

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a

Homotopic Heterotopic Ipsilateral

b

Corpus callosum

Corpus callosum

Plane of section in (b) (roughly premotor area)

FIGURE 4.9 Tracing connections between and within the cerebral cortices. (a) Midsagittal view of the right cerebral hemisphere, with the corpus callosum labeled. (b) The caudal surface of a coronal section of brain roughly through the premotor cortical area. Homotopic callosal fibers (blue) connect corresponding sections of the two hemispheres via the corpus callosum; heterotopic connections (green) link different areas of the two hemispheres of the brain. In primates, both types of contralateral connections (blue and green), as well as ispilateral connections (red), start and finish at the same layer of neocortex.

a

b FIGURE 4.10 Coronal sections at (a) the level of the posterior commissure and (b) the anterior commissure.

Anatomy of the Hemispheres | 131

HOW THE BRAIN WORKS

Interhemispheric Communication: Cooperation or Competition? Theories of callosal function generally have focused on the idea that this massive bundle of axonal fibers provides the primary pathway for interhemispheric transfer. For example, in Chapter 6 we will discuss Warrington’s model of object recognition. In her view, the right hemisphere performs a specialized operation essential for perceptual categorization. This operation is followed by a left-hemisphere operation for semantic categorization. Interhemispheric communication is essential in this model for shuttling the information through these two processing stages. On the other hand, interhemispheric communication need not be a cooperative process. Connections across the corpus callosum may underlie a competition between the hemispheres. Indeed, the primary mode of callosal communication may be inhibitory rather than excitatory. By this view, we need not assume that interhemispheric communication is designed to share information processing within the two hemispheres to facilitate concurrent, and roughly identical, activity in homologous regions. Similar to the way in which split-brain behavior is assumed to reflect the independent operation of the two hemispheres, behavior produced by intact brains may also reflect the (fluctuating) dominance of one or the other hemisphere. One challenge for a cooperative system is that there must be a means to ensure that the two hemispheres are operating on roughly the same information. Such coordination might be difficult, given that both the perceptual input and the focus of our attention are constantly changing. Although computers can perform their operations at lightning speed, neural activity is a relatively slow process. The processing delays inherent in transcallosal communication may limit the extent to which the two hemispheres can cooperate. A number of factors limit the rate of neural activity. First, to generate an action potential, activity within the receiving dendritic branches must integrate tiny inputs across both space and time in order to reach threshold. Second, the rate at which individual neurons can fire is limited, owing to intrinsic differences in membrane properties, tonic sources of excitation and inhibition, and refractory periods between spike-generating events. Third, and most important, neural signals need to be propagated along axons. These conduction times can be quite substantial, especially for the relatively long fibers of the corpus callosum. James Ringo and his colleagues (1994) at the University of Rochester provided an interesting analysis of this problem. They began by calculating estimates of transcallosal conduction delays. Two essential numbers were needed: the distance to be traveled, and the speed at which the signal would be transmitted. If the distances were direct, the average distance of the callosal fibers would be short. Most axons follow a circuitous route, however. Taking this point into consideration, a value of 175mm was used as representative of the average

length of a callosal fiber in humans. The speed at which myelinated neural impulses travel is a function of the diameter of the fibers. Using the limited data available from humans, in combination with more thorough measures in the monkey, the average conduction speed was estimated to be about 6.5m/s. Thus to travel a distance of 175 mm would take almost 30 ms. Single-cell studies in primates have confirmed that interhemispheric processing entails relatively substantial delays. Ringo used a neural network to demonstrate the consequences of slow interhemispheric conduction times. The network consisted of two identical sets of processing modules, each representing a cerebral hemisphere. It included both intrahemispheric and interhemispheric connections; the latter were much sparser to reflect the known anatomy of the human brain. This network was trained to perform a pattern recognition task. After it had learned to classify all of the patterns correctly, the interhemispheric connections were disconnected. Thus, performance could now be assessed when each hemisphere had to operate in isolation. The critical comparison was between networks in which the interhemispheric conduction times during learning had been either slow or fast. The results showed that, for the network trained with fast interhemispheric connections, the disconnection procedure led to a substantial deterioration in performance. Thus, object recognition was dependent on cooperative processing for the network with fast interhemispheric connections. In contrast, for the network trained with slow interhemispheric connections, performance was minimally affected by the disconnection procedure. For this network, recognition was essentially dependent only on intrahemispheric processing. These results led Ringo to conclude that a system with slow interhemispheric conduction delays—for example, the human brain—ends up with each hemisphere operating in a relatively independent manner. Interestingly, these delays could be reduced if the callosal fibers were larger because the larger size would increase conduction speed. Larger fibers, however, would require a corresponding increase in brain volume. For example, reducing the conduction delay by a factor of two would lead to a 50% increase in brain volume. Such an increase would have severe consequences for metabolic demands as well as for childbirth. The brain appears to have evolved such that each hemisphere can have rapid access to information from either side of space, but with limited capability for tasks that would require extensive communication back and forth across the corpus callosum. The delays associated with transcallosal communication not only might limit the degree of cooperation between two hemispheres but also might have provided an impetus for the development of hemispheric specialization. Independent processing systems would be more likely to evolve non-identical computational capabilities.

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Two separate light bars moving in different directions

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A long light bar spanning both fields

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FIGURE 4.11 Synchrony in cortical neurons. (a) When receptive fields (1 and 2) on either side of fixation are stimulated by two separate light bars moving in different directions (as indicated by the arrows), the firing rates of the two cells are not correlated. (b) In animals with an intact corpus callosum, cells with spatially separate receptive fields fire synchronously when they are stimulated by a common object, such as a long light bar spanning both fields. (c) In animals whose corpus callosum has been severed, synchrony is rarely observed.

Callosal connections in the adult, however, are a scaled-down version of what is found in immature individuals. In developing animals, callosal projections are diffuse and more evenly distributed across the cortical surface. Cats and monkeys lose approximately 70 % of their callosal axons during development; some of these transient projections are between portions of the primary sensory cortex that, in adults, are not connected by the callosum. Yet this loss of axons does not produce cell death in each cortical hemisphere. This is because a single cell body can send out more than one axon terminal: one to cortical areas on the same side of the brain, and one to the other side of the brain. Thus, loss of a callosal axon may well leave its cell body—with its secondary collateral connection to the ipsilateral hemisphere—alive and well, just like pruning a bifurcating peach tree branch leaves the branch thriving. The refinement of connections is a hallmark of callosal development, just as such refinement characterizes intrahemispheric development (see Chapter 2). In general terms, hemispheric specialization must have been influenced and constrained by callosal evolution. The appearance of new cortical areas might be expected to require more connections across the callosum (i.e., expansion). In contrast, lateralization might have been facilitated by a lack of callosal connections. The

resultant isolation would promote divergence among the functional capabilities of homotopic regions, resulting in cerebral specializations. As with the cerebral hemispheres, researchers have investigated functional correlates of anatomical differences in the corpus callosum. Usually, investigators measure gross aspects like the cross-sectional area or shape of the callosum. Variations in these measures are linked to gender, handedness, mental retardation, autism, and schizophrenia. Interpretation of these data, however, is complicated by methodological disagreements and contradictory results. The underlying logic of measuring the corpus callosum’s cross-sectional area relies on the relation of area to structural organization. Callosal size could be related to the number and diameter of axons, the proportion of myelinated axons, the thickness of myelin sheaths, and measures of nonneural structures such as the size of blood vessels or the volume of extracellular space with resultant functional differences. Among large samples of callosal measurements from age-matched control subjects, sex-based differences are seen in the shape of the midsagittal sections of the callosum but not in its size. More recently, studies looking at the parasagittal size and asymmetry of the corpus callosum have found an increased rightward callosal

Splitting the Brain: Cortical Disconnection | 133 asymmetry in males compared to females (Lunder et al., 2006). That is, a larger chunk of the callosum bulges off to the right side in males. It may be that what side of the hemispheric fence the major part of the callosum sits on is the important factor. Thus, this sexually dimorphic organization of the corpus callosum (more on the right than the left in males) may involve not just the corpus callosum, but asymmetric hemispheric development also, reflected in the distribution of parasagittal callosal fibers (Chura et al., 2009). This structure could in turn account for the observed patterns of accelerated language development in females, who have more acreage in the left hemisphere, and the enhanced performance in males during visuospatial tasks and increased rate of left-handedness in males thanks to their rightward bulge. Tantalizing research by Linda Chura and her colleagues found that with increasing levels of fetal testosterone, there was a significantly increasing rightward asymmetry (e.g., right . left) of a posterior subsection of the callosum, called the isthmus, that projects mainly to parietal and superior temporal areas.

TAKE-HOME MESSAGES ■

The Wada test is used to identify which hemisphere is responsible for language before brain surgery is performed. The two halves of the cerebral cortex are connected primarily by the corpus callosum, which is the largest fiber system in the brain. In humans, this bundle of white matter includes more than 250 million axons. Two smaller bands of fibers, the anterior and posterior commissures, also connect the two hemispheres. The corpus callosum has both homotopic and heterotopic connections. Homotopic fibers connect the corresponding regions of each hemisphere (e.g., V1 on the right to V1 on the left), whereas heterotopic fibers connect different areas (e.g., V1 on the right to V2 on the left). Differences in neural connectivity and organization may underlie many of the gross asymmetries between the hemispheres. Ninety-six percent of humans, regardless of which hand is dominant, have a left-hemisphere specialization for language. The planum temporale encompasses Wernicke’s area and is involved in language. The asymmetry of the planum temporale is one of the few examples in which an anatomical index is correlated with a well-defined functional asymmetry. Differences have been found in the specifics of cortical microcircuitry between the two hemispheres in both anterior (Broca’s) and posterior (Wernicke’s) languageassociated cortex.

Splitting the Brain: Cortical Disconnection Because the corpus callosum is the primary means of communication between the two cerebral hemispheres, we learn a great deal when we sever the callosal fibers. This approach was successfully used in the pioneering animal studies of Ronald Myers and Roger Sperry at the California Institute of Technology. They developed a series of animal experiments to assess whether the corpus callosum is crucial for unified cortical function. First, they trained cats to choose a “plus” stimulus versus a “circle” stimulus randomly alternated between two doors. When a cat chose correctly, it was rewarded with food. Myers and Sperry made the startling discovery that when the corpus callosum and anterior commissure were sectioned, such visual discriminations learned by one hemisphere did not transfer to the other hemisphere. Further studies done on monkeys and chimpanzees showed that visual and tactile information lateralized to one hemisphere did not transfer to the opposite hemisphere, thus corroborating the results from cats. This important research laid the groundwork for comparable human studies initiated by Sperry and one of the authors (MSG; Sperry et al., 1969). Unlike lesion studies, the split-brain operation does not destroy any cortical tissue; instead, it eliminates the connections between the two hemispheres. With split-brain patients, functional inferences are not based on how behavior changes after a cortical area is eliminated. Rather, it becomes possible to see how each hemisphere operates in relative isolation.

The Surgery Corpus callosotomy, or split-brain surgery, is used to treat intractable epilepsy when other forms of treatment, such as medication, have failed. This procedure was first performed in 1940 by a Rochester, New York, surgeon, William Van Wagenen. One of Van Wagenen’s patients, who had a history of severe epileptic seizures, improved after developing a tumor in his corpus callosum (Van Wagenen & Herren, 1940). Epileptic seizures are the result of abnormal electrical discharges that zip across the brain. The improvement in his patient’s condition gave Van Wagenen the idea that if he were to sever the patient’s corpus callosum, perhaps the electrical impulses causing seizures would be unable to spread from one hemisphere to the other: The epileptogenic activity would be held in check, and a generalized seizure would be prevented. The idea was radical, particularly when so little was really understood about brain function. The surgery itself was also painstaking, especially without today’s

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microsurgical techniques, because only a thin wall of cells separates the ventricles from the corpus callosum. With the limited treatment options available at the time, however, Van Wagenen had desperate patients; and to twist a phrase, they called for desperate measures. One great fear loomed: What would be the side effect—a split personality with two minds fighting for control over one body? To everyone’s relief, the surgery was a great success. Remarkably, the patients appeared and felt completely normal. The seizures typically subsided immediately, even in patients who, before the operation, experienced up to 15 seizures per day. Eighty percent of the patients enjoyed a 60 % to 70 % decrease in seizure activity, and some were free of seizures altogether (Akelaitis, 1941). Everyone was happy, yet puzzled. Twenty of the surgeries were performed without any discernible psychological side effects: no changes to the psyche, personality, intellect, sensory processing, or motor coordination. Akelaitis concluded: The observations that some of these patients were able to perform highly complex synchronous bilateral activities as piano-playing, typewriting by means of the touch system and dancing postoperatively suggests strongly that commissural pathways other than the corpus callosum are being utilized. (Akelaitis, 1943, p. 259)

Methodological Considerations in Studying Split-Brain Patients A number of methodological issues arise in evaluations of the performance of split-brain patients. First, bear in mind that these patients were not neurologically normal before the operation; they were all chronic epileptics, whose many seizures may have caused neurologic damage. Therefore, it is reasonable to ask whether they provide an appropriate barometer of normal hemispheric function after the operation. There is no easy answer to this question. Several patients do display abnormal performance on neuropsychological assessments, and they may even be mentally retarded. In some patients, however, the cognitive impairments are negligible; these are the patients studied in closest detail. Second, it is important to consider whether the transcortical connections were completely sectioned, or whether some fibers remained intact. In the original California operations, reviewing surgical notes was the only way to determine the completeness of the surgical sections. In recent years though, MRIs, such as in Figure 4.12, diffusion tensor imaging, and electrical brainmapping techniques have provided a more accurate representation of the extent of surgical sections. Accurate documentation of a callosal section is crucial for learning about the organization of the cerebral commissure.

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FIGURE 4.12 This MRI shows a sagittal view of a brain in which the corpus callosum has been entirely sectioned.

The main methods of testing the perceptual and cognitive functions of each hemisphere have changed little over the past 30 years. Researchers use primarily visual stimulation, not only because of the preeminent status of this modality for humans but also because the visual system is more strictly lateralized (see Figure 4.1) than are other sensory modalities, such as the auditory and olfactory systems. The visual stimulus is restricted to a single hemisphere by quickly flashing the stimulus in one visual field or the other (Figure 4.13). Before stimulation, the patient is required to fixate on a point in space. The brevity of

Speech Left hand

“Ring”

RING KEY

FIGURE 4.13 Restricting visual stimuli to one hemisphere. The split-brain patient reports through the speaking hemisphere only the items flashed to the right half of the screen and denies seeing left-field stimuli or recognizing objects presented to the left hand. Nevertheless, the left hand correctly retrieves objects presented in the left visual field, about which the patient verbally denies knowing anything.

Splitting the Brain: Cortical Disconnection | 135 stimulation is necessary to prevent eye movements, which would redirect the information into the unwanted hemisphere. Eye movements take roughly 200 ms, so if the stimulus is presented for a briefer period of time, the experimenter can be confident that the stimulus was lateralized. More recent image stabilization tools— tools that move in correspondence with the subject’s eye movements—allow a more prolonged, naturalistic form of stimulation. This technological development has opened the way for new discoveries in the neurological and psychological aspects of hemisphere disconnection.

Functional Consequences of the Split-Brain Procedure The results of testing done on the patient W.J. were contrary to the earlier reports on the effects of the split-brain procedure as reported by A. J. Akelaitis (1941), who had found no significant neurological and psychological effects after the callosum was sectioned. Careful testing with W.J. and other California patients, however, revealed behavioral changes similar to those seen in split-brain primates (see below). Visual information presented to one half of the brain was not available to the other half. The same principle applied to touch. Patients were able to name and describe objects placed in the right hand but not objects presented in the left hand. Sensory information restricted to one hemisphere was also not available to accurately guide movements with the ipsilateral hand. For example, when a picture of a hand portraying the “OK” sign was presented to the left hemisphere, the patient was able to make the gesture with the right hand, which is controlled from the left half of the brain. The patient was unable to make the same gesture with the left hand, however, which is controlled from the disconnected right hemisphere. From a cognitive point of view, these initial studies confirmed long-standing neurological knowledge about the nature of the two cerebral hemispheres, which had been obtained earlier from patients with unilateral hemispheric lesions: The left hemisphere is dominant for language, speech, and major problem solving. Its verbal IQ and problem-solving capacity (including mathematical tasks, geometric problems, and hypothesis formation) remain intact after callosotomy (Gazzaniga, 1985). Isolating half the brain, cutting its acreage by 50 %, causes no major changes in cognitive function—nor do the patients notice any change in their abilities. The right hemisphere is impoverished in its ability to perform cognitive tasks, but it appears specialized for visuospatial tasks such as drawing cubes and other three-dimensional patterns. The split-brain patients cannot name or describe visual and tactile stimuli presented to the right hemisphere,

because the sensory information is disconnected from the dominant left (speech) hemisphere. This does not mean that knowledge about the stimuli is absent in the right hemisphere, however. Nonverbal response techniques are required to demonstrate the competence of the right hemisphere. For example, the left hand can be used to point to named objects or to demonstrate the function of depicted objects presented in the left visual field.

Split-Brain Evidence for Callosal Function Specificity We have seen that when the corpus callosum is fully sectioned, little or no perceptual or cognitive interaction occurs between the hemispheres. Surgical cases in which callosal section is limited or part of the callosum is inadvertently spared have enabled investigators to examine specific functions of the callosum by region. For example, when the splenium, the posterior area of the callosum that interconnects the occipital lobe, is spared, visual information is transferred normally between the two cerebral hemispheres (Figure 4.14). In these instances, pattern, color, and linguistic information presented anywhere in either visual field can be matched with information presented to the other half of the brain. The patients, however, show no evidence of interhemispheric transfer of tactile information from touched objects. Tactile information turns out to be transferred by fibers in a region just anterior to the splenium, still located in the posterior half of the callosum. Surgeons sometimes perform the split-brain procedure in stages, restricting the initial operation to the front (anterior) or back (posterior) half of the callosum. The remaining fibers are sectioned in a second operation

FIGURE 4.14 An incomplete corpus callostomy. MRI scan showing that the splenium (arrow) was spared in the split-brain procedure performed on this patient. As a result, visual information can still be transferred between the cerebral hemispheres.

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Right-hemisphere stimulus

Left-hemisphere verbal response Normal brain

Knight

"Knight"

The splenium is the most posterior portion of the corpus callosum. When the posterior half of the callosum is sectioned in humans, transfer of visual, tactile, and auditory sensory information is severely disrupted. The anterior part of the callosum is involved in the higher order transfer of semantic information.

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"I have a picture in mind but can't say it. Two fighters in a ring. Ancient and wearing uniforms and helmets...on horses...trying to knock each other off...Knights?"

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FIGURE 4.15 Schematic representation of split-brain patient J.W.’s naming ability for objects in the left visual field at each operative stage.

only if the seizures continue to persist. This two-stage procedure offers a unique glimpse into what the anterior and posterior callosal regions transfer between the cerebral hemispheres. When the posterior half of the callosum is sectioned, transfer of visual, tactile, and auditory sensory information is severely disrupted, but the remaining intact anterior region of the callosum is still able to transfer higher order information. For example, one patient (J.W.) was able to name stimuli presented in the left visual field following a resection limited to the posterior callosal region. Close examination revealed that the left hemisphere was receiving higher order cues about the stimulus without having access to the sensory information about the stimulus itself (Figure 4.15). In short, the anterior part of the callosum transfers semantic information about the stimulus but not the stimulus itself. After the anterior callosal region was sectioned in this patient, this capacity was lost.

TAKE-HOME MESSAGES ■

In some of the original animal studies on callosotomies, Myers and Sperry demonstrated that visual discrimination learned by one hemisphere did not transfer to the other hemisphere when the hemispheres were disconnected.

Hemispheric Specialization Evidence from Split-Brain Patients As we saw in Chapter 1, the history of cerebral specialization—the notion that different regions of the brain have specific functions—began with Franz Joseph Gall in the early 1800s. Although it fell repeatedly in and out of fashion, this idea could not be discounted, because so many clinical findings, especially in patients who had suffered strokes, provided unassailable evidence that it was so. Over the last 50 years, studies done with split-brain patients have demonstrated that some of the brain’s processing is lateralized. In this section, we review some of these findings. The most prominent lateralized function in the human brain is the left hemisphere’s capacity for language and speech, which we examine first. We also look at the lateralization of visuospatial processing, attention and perception, information processing, and how we interpret the world around us.

Language and Speech

When we are trying to understand the neural bases of language, it is useful to distinguish between grammatical and lexical functions. The grammar–lexicon distinction is different from the more traditional syntax–semantics distinction commonly invoked to improve understanding of the differential effects of brain lesions on language processes (see Chapter 11). Grammar is the rule-based system that humans have for ordering words to facilitate communication. For example, in English, the typical order of a sentence is subject (noun)—action (verb)—object (noun). The lexicon is the mind’s dictionary, where words are associated with specific meanings. A “dog” is, well, associated with a dog; but so is a chien and a cane, depending on the language that you speak. The grammar–lexicon distinction takes into account factors such as memory, because, with memory, word strings as idioms can be learned by rote. For example, “How are you?” or “Comment allez-vous?” is most likely a single lexical entry. Although the lexicon cannot possibly encompass the infinite number of unique phrases and sentences that humans can generate—such as the one

Hemispheric Specialization | 137 Latencies for both types of trials are much longer for the left visual field. 900 Compatible

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you are now reading—memory does play a role in many short phrases. When uttered, such word strings do not reflect an underlying interaction of syntax and semantic systems; they are, instead, essentially an entry from the lexicon. This is more apparent when you are learning a new language. You often learn stock phrases that you speak as a unit, rather than struggle with the grammar. With this in mind, it might be predicted that some brain areas ought to be wholly responsible for grammar, whereas the lexicon’s location ought to be more elusive, since it reflects learned information and thus is part of the brain’s general memory and knowledge systems. The grammar system, then, ought to be discrete and hence localizable, and the lexicon should be distributed and hence more difficult to damage completely. Language and speech are rarely present in both hemispheres; they are either in one or the other. While it is true that the separated left hemisphere normally comprehends all aspects of language, the linguistic capabilities of the right hemisphere do exist, although they are uncommon. Indeed, out of dozens of split-brain patients who have been carefully examined, only six showed clear evidence of residual linguistic functions in the right hemisphere. And even in these patients, the extent of righthemisphere language functions is severely limited and restricted to the lexical aspects of comprehension. Interestingly, the left and right lexicons of these special patients can be nearly equal in their capacity, but they are organized quite differently. For example, both hemispheres show a phenomenon called the word superiority effect (see Chapter 5). Normal English readers are better able to identify letters (e.g., L) in the context of real English words (e.g., belt) than when the same letters appear in pseudowords (e.g., kelt) or nonsense letter strings (e.g., ktle). Because pseudowords and nonwords do not have lexical entries, letters occurring in such strings do not receive the additional processing benefit bestowed on words. Thus, the word superiority effect emerges. While the patients with right-hemisphere language exhibit a visual lexicon, it may be that each hemisphere accesses this lexicon in a different way. To test this possibility, investigators used a letter-priming task. Participants were asked to indicate whether a briefly flashed uppercase letter was an H or a T. On each trial, the uppercase letter was preceded by a lowercase letter that was either an h or a t. Normally, participants are significantly faster, or primed, when an uppercase H is preceded by a lowercase h than when it is preceded by a lowercase t. The difference between response latency on compatible (h–H) versus incompatible (t–H) trials is taken to be a measure of letter priming. J.W., a split-brain participant, performed a lateralized version of this task

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FIGURE 4.16 Letter priming as a function of visual field in splitbrain patients. The graph shows the response latencies for compatible and incompatible pairs of letters in the left and right visual fields (LVF and RVF, respectively). The latencies for both types of trials are much longer for the left visual field (right hemisphere).

in which the prime was displayed for 100 ms to either the right or the left visual field, and 400 ms later the target letter appeared in either the right or the left visual field. The results, shown in Figure 4.16, provide no evidence of letter priming for left visual field (LVF) trials but clear evidence of priming for trials of the right visual field (RVF). Thus, the lack of a priming phenomenon in the disconnected right hemisphere suggests a deficit in letter recognition, prohibiting access to parallel processing mechanisms. J.W. exhibited a variety of other deficiencies in right-hemisphere function as well. For example, he was unable to judge whether one word was superordinate to another (e.g., furniture and chair), or whether two words were antonyms (e.g., love and hate). In sum, there appear to be two lexicons, one in each hemisphere. The right hemisphere’s lexicon seems organized differently from the left hemisphere’s lexicon, and these lexicons are accessed in different ways. These observations are consistent with the view that lexicons reflect learning processes and, as such, are more widely distributed in the cerebral cortex. A long-held belief has been that in the general population, the lexicon appears to be in the left hemisphere. Recent evidence from functionalimaging studies, however, suggests a broader role for the right hemisphere in language processing, although the precise nature of that role remains to be defined. Some theorists have suggested that the language ability of the left hemisphere gives it a superior ability to perform higher cognitive functions like making inferences and solving mathematics problems. Split-brain patients who have an extensive right-brain lexicon, however, do not show any attendant increase in their right brain’s ability to perform these tasks (Gazzaniga & Smylie, 1984).

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In contrast, generative syntax is present in only one hemisphere. Generative syntax means that by following rules of grammar, we can combine words in an unlimited number of meanings. Although the right hemisphere of some patients clearly has a lexicon, it performs erratically on other aspects of language, such as understanding verbs, pluralizations, the possessive, or active–passive differences. In these patients, the right hemisphere also fails to use word order to disambiguate stimuli for correct meaning. For instance, the meaning of the phrase “The dog chases the cat” cannot be differentiated from the meaning of “The cat chases the dog.” Yet these right hemispheres can indicate when a sentence ends with a semantically odd word. “The dog chases cat the” would be flagged as wrong. What’s more, right hemispheres with language capacities can make grammar judgments. For some peculiar reason, although they cannot use syntax to disambiguate stimuli, they can judge that one set of utterances is grammatical while another set is not. This startling finding suggests that patterns of speech are learned by rote. Yet recognizing the pattern of

acceptable utterances does not mean that a neural system can use this information to understand word strings (Figure 4.17). A hallmark of most split-brain patients is that their speech is produced in the left hemisphere and not the right. This observation, along with amobarbital studies (see Wada and Rasmussen, 1960) and functional imaging studies, confirms that the left hemisphere is the dominant hemisphere for speech production in most (96 %) of us. Nonetheless, there are now a handful of documented cases of split-brain patients who can produce speech from both the left and the right hemispheres. Although speech is restricted to the left hemisphere following callosal bisection, in these rare patients the capacity to make oneword utterances from the disconnected right hemisphere has emerged over time. This intriguing development raises the question of whether information is somehow transferring to the dominant hemisphere for speech output or whether the right hemisphere itself is capable of developing speech production. After extensive testing, it became apparent that the latter hypothesis was correct.

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FIGURE 4.17 Cognitive abilities of the right hemisphere. (a) The right hemisphere is capable of understanding language but not syntax. When presented with a horse stimulus in the left visual field (right hemisphere), the subject maintains through the left hemisphere that he saw nothing. When asked to draw what goes on the object, the left hand (right hemisphere) is able to draw a saddle. (b) The capacity of the right hemisphere to make inferences is extremely limited. Two words are presented in serial order, and the right hemisphere (left hand) is simply required to point to a picture that best depicts what happens when the words are causally related. The left hemisphere finds these tasks trivial, but the right cannot perform the task. (c) Data from three patients show that the right hemisphere is more accurate than the left in recognizing unfamiliar faces.

Hemispheric Specialization | 139 For example, the patients were able to name an object presented in the left field, say a spoon, and in the right field, a cow, but were not able to judge whether the two objects were the same. Or, when words like father were presented such that the fixation point fell between the t and the h, the patients said either “fat” or “her,” depending on which hemisphere controlled speech production. These findings illustrate that an extraordinary plasticity lasts sometimes as long as 10 years after callosal surgery. In one patient, in fact, the right hemisphere had no speech production capability for approximately 13 years before it “spoke.” Finally, note that although most language capabilities are left lateralized, the processing of the emotional content of language appears to be right lateralized. It is well known that patients with damage to certain regions of the left hemisphere have language comprehension difficulties. Speech, however, can communicate emotion information beyond the meanings and structures of the words. A statement, such as “John, come here,” can be interpreted in different ways if it is said in an angry tone, a fearful tone, a seductive tone, or a surprised tone. This nonlinguistic, emotional component of speech is called emotional prosody. One patient with left-hemisphere damage reportedly has difficulty comprehending words but shows little deficit in interpreting the meaning of emotional prosody (Barrett et al., 1999). At the same time, several patients with damage to the temporoparietal lobe in the right hemisphere have been shown to comprehend the meaning of language perfectly but have difficulty interpreting phrases when emotional prosody plays a role (Heilman et al., 1975). This double dissociation between language and emotional prosody in the comprehension of meaning suggests that the right hemisphere is specialized for comprehending emotional expressions of speech.

Visuospatial Processing Early testing of W.J. made it clear that the two hemispheres have different visuospatial capabilities. As Figure 4.2 shows, the isolated right hemisphere is frequently superior on neuropsychological tests such as the block design task, a subtest of the Wechsler Adult Intelligence Scale. In this simple task of arranging red and white blocks to match a given pattern, the left hemisphere of a split-brain patient performs poorly while the right hemisphere easily completes the task. Functional asymmetries like these, however, have proven to be inconsistent. In some patients, performance is impaired with either hand; in others, the left hemisphere is quite adept at this task. Perhaps a component of this task, rather than the whole task, is lateralized. Additional testing has shown that patients who demonstrate a right-hemisphere superiority for the block design task exhibit no asymmetry on the perceptual aspects of the task (contrary to what you may have predicted). If a picture of the block design pattern is lateralized, either hemisphere can easily find the match from a series of pictures. Since each hand is sufficiently dexterous, the crucial link must be in the mapping of the sensory message onto the capable motor system. The right hemisphere is also specialized for efficiently detecting upright faces and discriminating among similar faces (Gazzaniga & Smylie, 1983). The left hemisphere is not good at distinguishing among similar faces, but it is able to distinguish among dissimilar ones when it can tag the feature differences with words (blond versus brunette, big nose versus button nose). As for the recognition of familiar faces in general, the right hemisphere outperforms the left hemisphere in this task (Turk, 2002). What about that most familiar of faces, one’s own? In one study, software was used to morph the face of one split brain patient J.W. in 10 % increments, into that of a familiar other, Mike (Figure 4.18). The faces were

FIGURE 4.18 Morphed images of J.W. and M.G. The image on the far left contains 10% M.G. and 90% J.W. and changes in 10% increments from left to right, to 90% M.G. and 10% J.W. on the far right. The two original photographs of M.G. and J.W. pictured above and these nine morphed images were presented to each hemisphere randomly.

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flashed randomly to J.W.’s separated hemispheres. Then that hemisphere was asked, in the first condition, “Is that you?” and, in another condition, “Is that Mike?” A double dissociation was found (Figure 4.19). The left hemisphere was biased towards recognizing one’s own face, while the right hemisphere had a recognition bias for familiar others (Turk et al., 2002). Both hemispheres can generate spontaneous facial expressions, but you need your left hemisphere to produce voluntary facial expressions. Indeed, people appear to have two neural systems for controlling facial expressions (Figure 4.20; Gazzaniga & Smylie, 1990). The left hemisphere sends its messages directly to the contralateral facial nucleus via cranial nerve VII, which in turn innervates the right facial muscles. At the same time, it also sends a command over the corpus callosum to the right half of the brain. The right hemisphere sends the message down to the left facial nucleus, which in turn innervates the left half of the face. The result is that a person can make a symmetrical voluntary facial response, such as a smile or frown. When a split-brain patient’s left hemisphere is given the command to smile, however, the lower right side of the face responds first while the left side responds about 180 msec later. Why does the left side respond at all? Most likely the signal is rerouted through secondary ipsilateral pathways that connect to both facial nuclei, which then eventually send the signal over to the left-side facial muscles.

Unlike voluntary expressions, which only the left hemisphere can trigger, spontaneous expressions can be managed by either half of the brain. When either half triggers a spontaneous response, the pathways that activate the brainstem nuclei are signaled through another pathway—one that does not course through the cortex. Each hemisphere sends signals straight down through the midbrain and out to the brainstem nuclei, which then signal the facial muscles. Clinical neurologists know of the distinction between these two ways of controlling facial muscles. For example, a patient with a lesion in the part of the right hemisphere that participates in voluntary expressions is unable to move the left half of the face when told to smile. But the same patient can easily move the left half of the face when spontaneously smiling, because those pathways are unaffected by right-hemisphere damage. In contrast, patients with Parkinson’s disease, whose midbrain nuclei no longer function, are unable to produce spontaneous facial expressions, whereas the pathways that support voluntary expressions work fine. Such patients can lose their masked-face appearance when asked to smile (Figure 4.21).

The Interactions of Attention and Perception The attentional and perceptual abilities of split-brain patients have been extensively explored. After cortical disconnection, perceptual information is not shared between the two cerebral hemispheres. Sometimes the supporting

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FIGURE 4.20 The neural pathways that control voluntary and spontaneous facial expression are different. (a) Voluntary expressions that can signal intention have their own cortical networks in humans. (b) The neural networks for spontaneous expressions involve older brain circuits and appear to be the same as those in chimpanzees. (inset) The location of the section that has been overlaid onto each face.

cognitive processes of attentional mechanisms, however, do interact. Some forms of attention are integrated at the subcortical level, and other forms act independently in the separated hemispheres. We noted earlier that split-brain patients cannot integrate visual information between the two visual

FIGURE 4.21 Facial expressions of two kinds of patients. The patient in the upper row suffered brain damage to the right hemisphere. (a) The lesion did not interfere in spontaneous expression but (b) it did interfere with voluntary expression. (c) This Parkinson’s disease patient has a typical masked face. Because Parkinson’s disease involves the part of the brain that controls spontaneous facial expression, the faces of these patients, when they are told to smile (d), light up because the other pathway is stillintact.

fields. When visual information is lateralized to either the left or the right disconnected hemisphere, the unstimulated hemisphere cannot use the information for perceptual analysis. This is also true for certain types of somatosensory information presented to each hand. Although touching any part of the body is noted by either hemisphere, patterned somatosensory information is lateralized. Thus, when holding an object in the left hand, a split-brain patient is unable to find an identical object with the right hand. Some investigators argue that higher order perceptual information is integrated by way of subcortical structures, but others have not replicated these results. For example, split-brain patients sometimes drew pictures that combined word information presented to the two hemispheres. When “ten” was flashed to one

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hemisphere and “clock” was flashed to the other, the patient drew a clock set at 10. This outcome initially seemed to imply that subcortical transfer of higher order information was taking place between the hemispheres. Subsequent observations (Figure 4.22; Kingstone & Gazzaniga, 1995), however, suggested that it actually reflects dual hemispheric control of the drawing hand (with control biased to the left hemisphere). When conceptually ambiguous word pairs, such as hot dog, were presented, they were always depicted literally (e.g., a dog panting in the heat) and never as emergent objects (e.g., a frankfurter). This suggests that no transfer of higher order information occurred. Moreover, right- and lefthand drawings often depicted only the words presented to the left hemisphere. The subcortical transfer of information is more apparent than real. We have seen that object identification seems to occur in isolation in each hemisphere of split-brain patients. In other studies, evidence suggested that crude information concerning spatial locations can be integrated

between the hemispheres. In one set of experiments, the patient fixated on a central point located between two 4-point grids, one in each visual field (Holtzman, 1984). In a given trial, one of the positions on one of the grids was highlighted for 500 msec. Thus information went in to either the left hemisphere or the right hemisphere, depending on which grid was illuminated. For example, in Figure 4.23a, the upper-left point of the grid in the left visual field was highlighted. This information would be registered in the right hemisphere of the subject. After 1 sec, a tone sounded and the subject was asked to move her eyes to the highlighted point within the visual field with the highlighted stimulus. The results were as expected. Information from the left visual field that went to the right hemisphere guided eye movement back to the same location where the light flashed. In the second condition, the subject was required to move her eyes to the relative point in the visual field opposite to the one with the highlighted stimulus (Figure 4.23b). If she could do this, it would mean that information about the location of light stimulus was coming in to the left hemisphere from the right visual field and was guiding her eye movement to the analogous location in the right-brain-controlled left visual field. Split-brain subjects did this task easily. So some type of spatial information is transferred and integrated between the two half brains, enabling attention to be transferred to either visual field. The ability remained intact even when the grid was randomly positioned in the test field. These results raised a question: Are the attentional processes associated with spatial information affected by cortical disconnection? As we will see in Chapter 7, surprisingly, split-brain patients can use either hemisphere to direct attention to positions in either the left or the right visual field. This conclusion was based on studies

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Attentional resources are shared. The concept that attentional resources are limited should be distinguished from limitations in processing that are a result of other properties of the sensory systems. Even though the overall resources that a brain commits to a task appear constant,

the method of deploying them can vary depending on the task. For example, the time needed to detect a complex object increases as more items are added to the display. Normal control subjects require an additional 70 ms to detect the target when two extra items are added to the display, and another 70 ms for each additional pair of items. In split-brain patients, when the items are distributed across the midline of the visual field (so that objects are in both visual fields—that is, a bilateral array), as opposed to all being in one visual field, the increase in reaction time to added stimuli is cut almost in half (Figure 4.24) (Luck et al., 1989). Two half brains working separately can do the job in half the time that one whole brain can. Division of cognitive resources improved performance. Separation of the hemispheres seems to have turned a unified perceptual system into two simpler perceptual systems that, because they are unable to communicate, don’t “interfere” with each other. The large perceptual problem, which the normal brain faces, is broken down into smaller problems that a half brain

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using a modified version of the spatial cuing task (see Figure 7.8 on page 279). In this task, participants respond as quickly as possible upon detecting a target that appears at one of several possible locations. The target is preceded by a cue, either at the target location (a valid cue) or at another location (an invalid cue). Responses are faster on valid trials, indicating spatial orienting to the cued location. In split-brain patients, as with normal participants, a cue to direct attention to a particular point in the visual field was honored no matter which half of the brain was presented with the critical stimulus (Holtzman et al., 1981). These results suggest that the two hemispheres rely on a common orienting system to maintain a single focus of attention. The discovery that spatial attention can be directed with ease to either visual field raised the question of whether each separate cognitive system in the split-brain patient, if instructed to do so, could independently and simultaneously direct attention to a part of its own visual field. Can the right hemisphere direct attention to a point in the left visual field while the left hemisphere attends to a point in the right visual field? Normal subjects cannot divide their attention that way, but perhaps the split-brain operation frees the two hemispheres from this constraint. As it turns out, the answer is no. The integrated spatial attention system remains intact following cortical disconnection (Reuter-Lorenz & Fendrich, 1990). Thus, as in neurologically intact observers, the attentional system of split-brain patients is unifocal. They, like us, are unable to prepare simultaneously for events taking place in two spatially disparate locations. The dramatic effects on perception and cognition of disconnecting the cerebral hemispheres initially suggested that each hemisphere has its own attentional resources (Kinsbourne, 1982). If that model were true, then the cognitive operations of one hemisphere, no matter what the difficulty, would have little influence on the cognitive activities of the other. The left brain could be solving a differential equation while the right brain was planning for next weekend. The alternative view is that the brain has limited resources to manage such processes: If most of our resources are being applied to solving our math problems, then fewer resources are available for planning the weekend’s activities. This phenomenon has been studied extensively, and all of the results have confirmed that the latter model is correct: Our central resources are limited.

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FIGURE 4.24 Division of cognitive resources in split brain patients improved visual search performance. As more items are added to a set, for split brain patients the increase in reaction time for bilateral arrays is only half as fast as when all objects are confined to one side.

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can solve when each hemisphere perceives only half the problem. It appears as if the patient’s total information processing capacity has increased so that it is superior to that of normal participants. How can this be, if resources remain constant? This conundrum forces us to consider where resources are applied in a perceptual–motor task. It appears that each hemisphere employs a different strategy to examine the contents of its visual field. The left hemisphere adopts a helpful cognitive strategy in solving the problem, whereas the right hemisphere does not possess those extra cognitive skills. This phenomenon was shown in a different experiment. Here, the task was to find a black circle in a field of equally numbered black squares and gray circles. Randomly interspersed through the trials were “guided” trials, where the search for the black circle had a guide—that is, a clue: There were fewer black squares in a ratio of about 2:5. A cognitive or “smart” approach would be to use the clue: concentrating on the black colored figures should enable a subject to complete the task faster than concentrating on the circular shaped figures. In two out of three split-brain patients, the left, dominant hemisphere used the clue, which decreased its reaction time in the guided trials, but the right hemisphere did not (Kingstone et al., 1995). In control groups, 70 % of people have a faster reaction time to guided trials and use the “smart” strategy. This result indicates that not all people use guided search; but when they do, their left hemisphere is using it. This apparent discrepancy supports other evidence that multiple mechanisms of attention operate at different stages of visual search processing from early to late, some of which might be shared across the disconnected hemispheres and others of which might be independent. Thus, each hemisphere uses the available resources but at different stages of processing. What’s more, using a “smart strategy” does not mean the left hemisphere is always better at orienting attention. It depends on the job. For instance, the right hemisphere, superior in processing upright faces, automatically shifts attention to where a face is looking; but the left hemisphere does not have the same response to gaze direction (Kingstone et al., 2000). When thinking about neural resources and their limitations, people often consider the mechanisms that are being engaged while performing voluntary processing. For example, what is happening as we try to rub our stomach, pat our head, and do a calculus problem at the same time? Searching a visual scene, however, calls upon processes that may well be automatic, built-in properties of the visual system itself. Indeed, the hemispheres interact quite differently in how they control reflex and voluntary attention processes. It appears that reflexive automatic attention orienting is independent in the two hemispheres, as the right hemisphere’s automatic shifting of

FIGURE 4.25 Global and local representations. We represent information at multiple scales. At its most global scale, this drawing is of a house. We can also recognize and focus on the component parts of the house.

attention to gaze direction indicates. Voluntary attention orienting, however, is a horse of a different color. Here, it appears, the hemispheres are competing, and the left has more say (Kingstone et al., 1995). That these systems are distinct is reflected in the discovery that splitting brains has a different effect on the processes. Global and local processing. What is the picture in Figure 4.25? A house, right? Now describe it more fully. You might note its architectural style, and you might point out the detailing on the front door, the double hung windows running across the front façade, and the shingled roof. In recounting the picture, you would have provided a hierarchical description. The house can be described on multiple levels: Its shape and attributes indicate it is a house. But it is also a specific house, with a specific configuration of doors, windows, and materials. This description is hierarchical in that the finer levels of description are embedded in the higher levels. The shape of the house evolves from the configuration of its component parts—an idea that will be developed in Chapter 6. David Navon (1977) of the University of Haifa introduced a model task for studying hierarchical structure. He created stimuli that could be identified on two different levels (e.g., Figure 4.26). At each level, the stimulus contains an identifiable letter. The critical feature is that the letter defined by the global shape is composed of smaller letters (the local shape). In Figure 4.26a, for example, the global H is composed of local Fs. Navon was interested in how we perceive hierarchical stimuli. He initially found that the perceptual system first extracted the global shape. The time required to

Hemispheric Specialization | 145 a

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identify the global letter was independent of the identity of the constituent elements, but when it came to identifying the small letters, reaction time was slowed if the global shape was incongruent with the local shapes. Subsequent research qualified these conclusions. Global precedence does depend on object size and the number of local elements. Perhaps different processing systems are used for representing local and global information. Lynn Robertson and her colleagues (1988) found evidence that supports this hypothesis. Patients who have a lesion in either the left or right hemisphere were presented with local and global stimuli in the center of view (the critical laterality factor was whether the lesion was in the left or right hemisphere). Patients with left-side lesions were slow to identify local targets, and patients with right-side lesions were slow with global targets, demonstrating that the left hemisphere is more adept at representing local information and the right hemisphere is better with global information. Keep in mind that both hemispheres can abstract either level of representation, but they differ in how efficiently local and global information are represented. The right is better at the big picture, and the left is more detail oriented. Thus, patients with left-hemisphere lesions are able to analyze the local structure of a hierarchical stimulus, but they must rely on an intact right hemisphere, which is less efficient at abstracting local information. Further support for this idea comes from studies of local and global stimuli with split-brain patients

(Robertson et al., 1993). Here, too, patients generally identify targets at either level, regardless of the side of presentation. As with normal participants and patients with unilateral lesions, however, split-brain patients are faster at identifying local targets presented to the right visual field (i.e., the left hemisphere) and global targets presented to the left visual field (i.e., the right hemisphere).

Theory of Mind Theory of mind refers to our ability to understand that other individuals have thoughts, beliefs, and desires. In terms of laterality, theory of mind is an interesting case. You might expect theory of mind to be another hemispheric specialization, lateralized to the left hemisphere like language is, given its dependency on reasoning. Much of the prevailing research on theory of mind, however, suggests that if it is lateralized at all, it is lateralized to the right hemisphere. Many neuroimaging studies show a network of regions in both hemispheres engaged in theory of mind tasks, including the medial prefrontal cortex (PFC), posterior superior temporal sulcus (STS), precuneus, and the amygdala–temporopolar cortex (Figure 4.27). Rebecca Saxe and her colleagues (2009), however, have demonstrated in several fMRI studies, using a version of the false belief task (see Chapter 13), that the critical component of theory of mind, the attribution of beliefs to another person, is localized to the temporal parietal junction in

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FIGURE 4.27 Theory of mind tasks activate a network of regions bilaterally. These include the medial prefrontal cortex, posterior superior temporal sulcus, precuneus (hidden in the medial longitudinal fissure in the parietal lobe), and the amygdala-temporopolar cortex. The attribution of beliefs is located in the right hemisphere’s temporal parietal junction.

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the right hemisphere. This finding may sound merely interesting to you, but to split-brain researchers it was shocking. Think about it for a second. If this information about the beliefs of others is housed in the right hemisphere, and if, in split-brain patients, it isn’t transferred to the speaking, left hemisphere, wouldn’t you expect that these patients would suffer a disruption in social and moral reasoning? Yet they don’t. Split-brain patients act like everyone else. Do these findings also suggest that the recursive nature of thinking about the beliefs of another person is lateralized to the right hemisphere? A split-brain study by Michael Miller and colleagues at UCSB may provide some insight into these questions (M. Miller et al., 2010). They tested three full-callosotomy patients and three partial-callosotomy patients on a moral reasoning task that depended on the ability to attribute beliefs to another person (the same task, used above by Saxe and colleagues, that produced activations in the right hemisphere). The task involved hearing a scenario in which the actions of an agent conflicted with the beliefs of the agent. For example: Grace works in a chemical plant, and she is fixing coffee for her friend. She adds a white powder to her friend’s coffee, believing that the white powder is sugar. The white powder was mislabeled, however, and was actually quite toxic. Her friend drinks the coffee and dies. After hearing the scenario, the subject is asked this question: Was it morally acceptable for Grace to give the coffee to her friend? Participants with an intact corpus callosum would typically say that it was morally acceptable to give her friend the coffee, because they think Grace believed that the white powder was sugar and intended no harm. That is, they realize that Grace had a false belief. If the special mechanisms that attribute belief are lateralized to the right hemisphere, then the speaking left hemisphere of the split-brain patients should be cut off from those mechanisms. Split-brain patients would thus respond in a way that relies on the outcome of the actions (i.e., her friend died) and is not based on the beliefs of the actors. Children younger than age 4 typically respond in this way (because they do not yet have a fully developed theory of mind). Indeed, Miller and colleagues found that all of the split-brain patients responded that Grace’s action was morally unacceptable. This intriguing result leaves open a question: If splitbrain patients are cut off from this important theory-ofmind mechanism, then why don’t they act like severely autistic patients, who are unable to comprehend the thinking and beliefs of other people? Some scientists have suggested that the specialized mechanism observed in the right hemisphere may be used for the fast, automatic processing of belief attributions, and that slower, more deliberate reasoning mechanisms of the left hemisphere could perform the same function given time for deliberation. In fact,

Miller and colleagues observed that patients in the moral reasoning study were often uncomfortable with their initial judgments. They would offer spontaneous rationalizations for responding in a particular way. For example, in another scenario, a waitress knowingly served sesame seeds to somebody who she believed was highly allergic to them. The outcome, however, was harmless, because the person was not allergic. The patient judged the waitress’s action to be morally acceptable. Some moments later, however, he appeared to rationalize his response by saying, “Sesame seeds are tiny little things. They don’t hurt nobody.” This patient had to square his automatic response, which did not benefit from information about the belief state of the waitress, with what he rationally and consciously knew is permissible in the world. This brings us to a discussion of the left brain interpreter mechanism.

The Interpreter A hallmark of human intelligence is our ability to make causal interpretations about the world around us, to formulate hypotheses and predictions about the events and actions in our lives, and to create a continuous sensible narrative about our place in the world. This ability allows us to adapt to a constantly changing world and easily solve problems that may arise. We make the causal interpretations almost on a moment-to-moment basis without realizing it. Imagine going to a movie on a sunny afternoon. Before entering the theater, you notice that the street and parking lot are dry, and only a few clouds are in the sky. Once the movie is over, however, and you walk back outside, the sky is gray and the ground is very wet. What do you instantly assume? You would probably assume that it rained while you were watching the movie. Even though you did not witness the rain and nobody told you that it had rained, you make that interpretation based on the evidence of the wet ground and gray skies. This ability to make interpretations is a critical component of our intellect. After a callosotomy surgery, the verbal intelligence and problem-solving skills of a split-brain patient remain relatively intact. There may be minor deficits, including free recall ability, but for the most part intelligence remains unchanged. An intact intelligence, however, is true only for the speaking left hemisphere, not for the right hemisphere. The intellectual abilities and problem-solving skills of the right hemisphere are seriously impoverished. A large part of the right hemisphere’s impoverishment can be attributed to the finding that causal inferences and interpretations appear to be a specialized ability of the left hemisphere. One of the authors (MSG) has referred to this unique specialization as the interpreter. The interpreter has revealed itself in many classic experiments over the years. A typical observation is when

Hemispheric Specialization | 147 the speaking left hemisphere offers up some kind of rationalization to explain the actions that were initiated by the right hemisphere, but whose motivation for the actions are unknown to the left hemisphere. For example, when the split-brain patient P.S. was given the command to stand up in a way that only the right hemisphere could view, P.S. stood up. When the experimenter asked him why he was standing, P.S.’s speaking left hemisphere immediately came up with a plausible explanation: “Oh, I felt like getting a Coke.” If his corpus callosum were intact, then P.S. would have responded that he stood up because that was the instruction he had received. The effects of the interpreter manifest itself in a number of ways. Sometimes it interprets the actions initiated by the right hemisphere, as in the example just described, but sometimes it interprets the moods caused by the experiences of the right hemisphere. Emotional states appear to transfer between the hemispheres subcortically, so severing the corpus callosum does not prevent the emotional state of the right hemisphere from being transferred to the left hemisphere, even though all of the perceptions and experiences leading up to that emotional state are still isolated. One of the authors (MSG) reported on a case in which he showed some negatively arousing stimuli to the right hemisphere alone. The patient denied seeing anything; but at the same time, she was visibly upset. Her left hemisphere felt the autonomic response to the emotional stimulus, but had no idea what had caused it. When asked what was upsetting, her left brain responded that the experimenter was upsetting her. In this case, the left hemisphere felt the valence of the emotion but was unable to explain the actual cause of it, so the interpreter constructed a theory from the available information. Probably the most notable example of the interpreter at work is an experiment done by Gazzaniga and Joseph LeDoux (1978) using a simultaneous concept task. A split-brain patient was shown two pictures, one exclusively to the left hemisphere and one exclusively to the right. Then he was asked to choose, from an array of pictures placed in full view in front of him, those that were associated with the pictures lateralized to the left and right sides of the brain (Figure 4.28). In one example of this kind of test, a picture of a chicken claw was flashed to the left hemisphere and a picture of a snow scene to the right hemisphere. Of the array of pictures placed in front of the subject, the obviously correct association is a chicken for the chicken claw and a shovel for the snow scene. Patient P.S. responded by choosing the shovel with the left hand and the chicken with the right. When asked why he chose these items, he (his left hemisphere) replied, “Oh, that’s simple. The chicken claw goes with the chicken, and you need a shovel to clean out the chicken shed.” Remember that the left brain has

FIGURE 4.28 The Interpreter at work. Split brain patient P.S. His left hemisphere had seen a chicken claw and his right hemisphere had seen a snow scene. When asked to point to a picture associated with the image he had just seen, his right hand (guided by his left hemisphere) pointed to the chicken (to go with the claw), and his left hand pointed to the shovel (“to clean out the chicken shed”).

no knowledge about the snow scene or why he picked the shovel. The left brain, having seen the left hand’s response, has to interpret that response in a context consistent with what it knows. What it knows is that there is a chicken, and his left hand is pointing to a shovel. It does not have a clue about a snow scene. What is the first sensible explanation it can come up with? Ahh—the chicken shed is full of chicken manure that must be cleaned out. The interpreter can affect a variety of cognitive processes. For example, it may be a major contributor to the distortion of memories. In a study by Elizabeth Phelps and one of the authors (MSG), split-brain patients were asked to examine a series of pictures that depicted an everyday storyline, such as a man getting out of bed and getting ready for work (Phelps & Gazzaniga, 1992). During a recognition test, the patients were shown an intermingled series of photos that included the previously studied pictures, new pictures unrelated to the storyline, and new pictures that were closely related to the storyline (Figure 4.29). The left hemisphere falsely recognized the new pictures related to the story, while the right hemisphere rarely made that mistake. Both hemispheres were equally good at recognizing the previously studied pictures and rejecting new unrelated pictures. The right

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Distractor picture (not related to story)

Distractor picture (related to story)

hemisphere, however, was more accurate at weeding out the new related pictures. Because of the left hemisphere’s tendency to make an inference that something must have occurred since it fit with its general schema of the event, it falsely recognized new related photos. George Wolford and colleagues at Dartmouth College also demonstrated this phenomenon using a probabilityguessing paradigm (Wolford et al., 2000). Participants were presented with a simple task of trying to guess which of two events would happen next. Each event had a different probability of occurrence (e.g., a red stimulus might appear 75 % of the time and a green one 25 % of the time), but the order of occurrence of the events was entirely random. There are two possible strategies for responding in this task: matching and maximizing. In the red–green example, frequency matching would involve guessing red 75 % of the time and guessing green 25 % of the time. Because the order of occurrence was random, this strategy potentially would result in a great number of errors. The second strategy, maximizing, involves simply guessing red every time. That approach ensures an accuracy rate of 75 % because red appeared 75 % of the time. Animals such as rats and goldfish maximize. Humans match. The result is that nonhuman animals perform better than humans in this task. The humans’ use of this suboptimal strategy has been attributed to a propensity to try to find patterns in sequences of events, even when we are told that the sequences are random. In Las Vegas casinos, the house maximizes; you don’t. We all know how that ends up. Wolford and colleagues tested each hemisphere of splitbrain patients using the probability-guessing paradigm.

FIGURE 4.29 Split-brain patients first examined a series of pictures that told the story of a man getting up in the morning and getting ready to go to work. A recognition test was done a while later testing each hemisphere separately. In this test the patients were shown a stack of pictures that included the original pictures and other pictures, some that had no relation to the story and others that could have been part of the story but weren’t.

They found that the left hemisphere used the frequencymatching strategy, whereas the right hemisphere maximized. When patients with unilateral damage to the left or right hemisphere were tested on the probability-guessing paradigm, the findings indicated that damage to the left hemisphere resulted in use of the maximizing strategy, whereas damage to the right hemisphere resulted in use of the suboptimal frequency-matching strategy. Together, these findings suggest that the right hemisphere outperforms the left hemisphere because the right hemisphere approaches the task in the simplest possible manner, with no attempt to form complicated hypotheses about the task. The left hemisphere, on the other hand, engages in the human tendency to find order in chaos. The left hemisphere persists in forming hypotheses about the sequence of events, even in the face of evidence that no pattern exists. Although this tendency to search for causal relationships has many potential benefits, it can lead to suboptimal behavior when there is no simple causal relationship. Some common errors in decision making are consistent with the notion that we are prone to search for and posit causal relationships, even when the evidence is insufficient or random. This search for causal explanations appears to be a left-hemisphere activity and is the hallmark of the interpreter. Note, however, that the right hemisphere is not devoid of causal reasoning. Matt Roser and colleagues (2005) discovered that while judgments of causal inference are best when the information is presented in the right visual field to the left hemisphere, judgments of causal perception are better when the information is presented in the left visual

Hemispheric Specialization | 149 field. In one experiment, Roser had both control and splitbrain participants watch a scenario in which two switches are pressed, either alone or together. When switch A is pressed, a light goes on; when B is pressed, it does not go on; when both are pressed, it does come on. When asked what caused the light to come on, only the left brain could make the inference that it was switch A. In a separate test, Roser had the same participants look at films of two balls interacting. Either one ball hits the second and it moves; one hits the second and there is a time gap before it moves; or one comes close, but there is a space gap, and the second one moves. The subject is asked if one ball caused the other to move. In this case, the right brain could determine the causal nature of the collision. These results suggest that the right hemisphere is more adept at detecting that one object is influencing another object in both time and space—computations essential for causal perception. To perceive objects in the environment as unified, the visual system must often extrapolate from incomplete information about contours and boundaries. Paul Corballis and colleagues (1999) used stimuli containing illusory contours to reveal that the right hemisphere can perceptually process some things better than the left can. As can be seen in Figure 4.30, both the left and right

FIGURE 4.30 The human right hemisphere can process some things better than the left. While either hemisphere can decide whether the illusory shapes in the left column are “fat” or “thin,” if outlines are added then only the right hemisphere can still tell the difference. The right hemisphere is able to perceive the whole when only a part is visible, known as amodal completion.

hemispheres perceived a fat shape in the top left figure and a skinny shape in the lower left figure, but only the right hemisphere could perceive the same shapes in the figures of amodal completion on the right side. Corballis termed this ability by the right hemisphere as the “right hemisphere interpreter.” The unique specialization of the left hemisphere— the interpreter—allows our mind to seek explanations for internal and external events in order to produce appropriate response behaviors. It is a powerful mechanism that, once glimpsed, makes investigators wonder how often our brains make spurious correlations. As we noted earlier and will see in Chapter 9, the interpreter also attempts to explain our emotional states and moods. Finally, as we discuss at the end of the chapter, this specialization offers us unique insight into the nature of our conscious awareness.

Evidence From Patients With Unilateral Cortical Lesions Research on hemispheric specialization has not been limited to split-brain studies. Many researchers have examined the performance of patients with unilateral, focal brain lesions, which we present in this section. We then close this portion of the chapter with some clever experimental designs that test the differential processing of the two hemispheres in people with intact brains. When testing patients having unilateral brain lesions, the basic idea has been to compare the performance of patients with right-hemisphere lesions against those with left-hemisphere lesions. An appealing feature of this approach is that there is no need to lateralize the stimuli to one side or the other. Laterality effects are assumed to arise because of the unilateral lesions. If lesions to the left hemisphere result in more disruption in reading tasks, for example, then the deficit is attributed to the hemisphere’s specialization in reading processes. To properly interpret these types of studies, it is necessary to carry out double dissociations (see Chapter 3) to determine whether similar lesions to the opposite hemisphere produce a similar deficit. For instance, it has been demonstrated consistently that lesions in the left hemisphere can produce deficits in language functions (such as speaking and reading) that are not seen in patients with comparable lesions to the right hemisphere. Similarly, lesions to the right hemisphere can disrupt spatial orientation, such as the ability to accurately locate visually presented items. Comparable lesions to the left hemisphere do not cause corresponding spatial deficits. Because information can travel along multiple pathways through the brain, it is important to study lateralization by comparing results of experiments using a number

Hemispheric Specialization

of independent methods. Are interhemispheric connections between the two halves of the cerebral cortex always necessary for spatial processing? Carol Colby and her colleagues at the University of Pittsburgh (Berman et al., 2005) used a clever method to ask if updating of spatial information can occur without a corpus callosum. They based their experiment on the understanding that our brain constructs a dynamic map of space as our eyes move about collecting visual information. Further, this information—stored as retinotopic coordinates—can be updated as we “scan” our memory to reconstruct where something was previously located. First, split-brain monkeys (including the anterior commissure), while focusing on a fixation point (FP in Figure 4.31), were shown two targets in succession: T1 remained on the screen, and T2 was rapidly extinguished. Next, the monkeys had to turn their gaze to T1 (first eye movement) and then, from memory, they were to look toward the location of T2 (second eye movement). Neurophysiological studies have shown that when the eyes move to the first target, the retinotopic coordinates of the second target are updated in our memory. Interestingly, when T2 was located between FP and T1, the memory trace of T2’s location shifts between the monkey’s hemispheres (see the lefthand panel in Figure 4.31a). This happens because T2 was seen in the right visual field when the monkey was staring at FP; but when its gaze shifts to T1, then the relative position of T2 is now left of the location of T1, so it is now considered to be in the left visual field, which is mapped onto the right hemisphere. (Recall that our visual system is highly contralateralized.) If this shift requires the corpus callosum, animals that have undergone the callosotomy procedure should fail miserably. And they do, for a while. Surprisingly, though, the animals quickly mastered the task (blue curve in Figure 4.31b). One hypothesis is that, in the absence of transcallosal connections, subcortical pathways may be sufficient to support the transfer of visuospatial information. In extreme cases in humans, however, the hemispheric biases for one level of representation can completely override other levels. In the case study at the beginning of this chapter, W.J. was unable to manipulate blocks into their global configuration when he was restricted to using his right hand. Similar dramatic things happen with stroke victims. Figure 4.32 displays drawings made by patients who recently had a stroke in either the right or the left hemisphere. They were shown a hierarchical stimulus and asked to reproduce it from memory. Drawings from patients with left-hemisphere lesions faithfully followed the contour, but without any hint of local elements. In contrast, patients with righthemisphere lesions produced only local elements. Note that this pattern was consistent whether the stimuli were

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FIGURE 4.31 Interhemispheric communication in split-brain monkeys. (a) Experimental setup; details are in the text. (b) Spatial error was measured by the difference between the end of the second eye movement and the target location. Accuracy was near perfect when the second eye movement was in the same direction as the first (red curve). During the initial test sessions, the monkey failed to move its eyes to the second location in the across-hemifield condition (blue curve) and generally moved its eyes straight above the end of the first eye movement. The increase in error starting around the fifth session occurred when the animal generated large eye movements in attempting to locate the second target. With subsequent sessions, performance quickly improved, and eventually the monkey was equally accurate in both conditions, suggesting that interhemispheric transfer could be accomplished by intact subcortical pathways.

linguistic or nonlinguistic; hence, the representational deficits were not restricted to certain stimuli. Note also that, because of the plasticity of the brain, such stark differences might dissipate and not be seen months after the stroke.

Evidence From the Normal Brain Researchers have also designed clever experiments to test the differential processing of the two hemispheres in people with intact brains. In the visual domain, comparisons are made between presentations of stimuli to the left or right visual field. Although this procedure ensures that information will be projected initially to the contralateral hemisphere, the potential for rapid transcortical transfer is high. Even so, consistent differences are

Hemispheric Specialization | 151 Linguistic stimulus Target stimulus

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Z Z ZZ ZZ Z Z Z Z Z Z Z Z Z Z Z Z Z Z Z a

simultaneously, one to each ear, and the subject tries to report both messages. The ipsilateral projections from each ear presumably are suppressed when a message comes over the contralateral pathway from the other ear. In a typical study, participants heard a series of dichotically presented words. When asked to repeat as many words as possible, participants consistently produced words that had been presented to the right ear—an effect dubbed the right-ear advantage (Figure 4.33b). Results like these mesh well with expectations that the left hemisphere is dominant for language.

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b FIGURE 4.32 Extreme failures of hierarchical processing following brain damage. Two patients were asked to draw the two figures shown in the left column of each panel. The patient with right-hemisphere damage was quite accurate in producing the local element—the Z in (a) or the square in (b)—but failed to arrange these elements into the correct global configuration. The patient with left-hemisphere damage drew the overall shapes but left out all of the local elements. Note that for each patient, the drawings were quite consistent for both the linguistic (a) and the nonlinguistic (b) stimuli, suggesting a task-independent representational deficit.

observed depending on which visual hemifield is stimulated. For example, participants are more adept at recognizing whether a briefly presented string of letters forms a word when the stimulus is shown in the right visual field than they are when it is presented in the left visual field. Such results led to the hypotheses that transfer of information between the hemispheres is of limited functional utility, or that the information becomes degraded during transfer. Thus, we conclude that performance is dominated by the contralateral hemisphere with peripheral visual input. Studies of auditory perception similarly attempt to isolate the input to one hemisphere. As in vision work, the stimuli can be presented monaurally—that is, restricted to one ear. Because auditory pathways are not as strictly lateralized as visual pathways (see Figure 5.3 on p. 168), however, an alternative methodology for isolating the input is the dichotic listening task shown in Figure 4.33a. In this task, introduced in the early 1970s by Doreen Kimura (1973), two competing messages are presented

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“...ball... ...table... ...nose... ...race car...”

b FIGURE 4.33 The dichotic listening task is used to compare hemispheric specialization in auditory perception. (a) Competing messages are presented, one to the left ear and one to the right ear. Auditory information is projected bilaterally. Although most of the ascending fibers from the cochlear nucleus project to the contralateral thalamus, some fibers ascend on the ipsilateral side. (b) Participants are asked either to report the stimuli or to judge whether a probe stimulus was part of the dichotic message. Comparisons focus on whether they heard the reported information in the right or left ear, with the assumption that the predominant processing occurred in the contralateral hemisphere. With linguistic stimuli, participants are more accurate in reporting the information presented to the right ear.

Hemispheric Specialization

The demonstration of visual and auditory performance asymmetries with lateralized stimuli generated great excitement among psychologists. Here at last were simple methods for learning about hemispheric specialization in neurologically healthy people. It is not surprising that thousands of laterality studies on healthy participants have been conducted using almost every imaginable stimulus manipulation. The limitations of this kind of laterality research should be kept in mind (Efron, 1990), however. ■

The effects are small and inconsistent, perhaps because healthy people have two functioning hemispheres connected by an intact corpus callosum that transfers information quite rapidly. There is a bias in the scientific review process to publish papers that find significant differences over papers that report no differences. It is much more exciting to report asymmetries in the way we remember lateralized pictures of faces than to report that effects are similar for right- and left-visual-field presentations. Interpretation is problematic. What can be inferred from an observed asymmetry in performance with lateralized stimuli? In the preceding examples, the advantages of the right visual field and the right ear were assumed to reflect that these inputs had better access to the language processes of the left hemisphere. Perhaps, however, people are just better at identifying information in the right visual field or in the right ear.

To rule out this last possibility, investigators must identify tasks that produce an advantage for the left ear or left visual field. For example, shortly after Kimura’s initial work, scientists discovered that people are better at recognizing the left-ear member of dichotic melody pairs; indeed, a double dissociation happens when participants are presented with dichotic pairs of sung melodies (Bartholomeus, 1974). We find a right-ear advantage for the song’s words but a left-ear advantage for its melodies (Figure 4.34).

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FIGURE 4.34 A right-ear advantage is not found on all tasks. Participants listened to a dichotic message in which each ear was presented with a series of letters sung to short melodies. When given a recognition memory test, participants were more accurate on the letters task for stimuli heard in the right ear. In contrast, a left-ear advantage was observed when the participants were tested on the melodies.

TAKE-HOME MESSAGES The left hemisphere is dominant for language, speech, and major problem solving; the right hemisphere appears specialized for visuospatial tasks such as drawing cubes and other three-dimensional patterns. Thus, split-brain patients cannot name or describe visual and tactile stimuli presented to the right hemisphere, because the sensory information is disconnected from the dominant left (speech) hemisphere. There may be two lexicons (associations of words with specific meanings), one in each hemisphere. The right

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hemisphere’s lexicon seems organized differently from the left hemisphere’s lexicon, and these lexicons are accessed in different ways. The right hemisphere has been linked to one aspect of speech perception, prosody, which is the connotative aspect of oral language—the way we vary articulation to convey affect or intonation. Some studies show that the right hemisphere is specialized for visuospatial processing. The right hemisphere has special processes devoted to the efficient detection of upright faces. The left hemisphere outperforms the right hemisphere when the faces are dissimilar, and the right hemisphere outperforms the left when the faces are similar. Although touching any part of the body is noted by either hemisphere, patterned somatosensory information is lateralized. Thus, a split-brain patient who is holding an object in the left hand is unable to find an identical object with the right hand. Surprisingly, split-brain patients can use either hemisphere to direct attention to positions in either the left or the right visual field.

The Evolutionary Basis of Hemispheric Specialization | 153 ■

The right hemisphere appears to be specialized for causal perception (the ability to detect that one object is influencing another object in both time and space), and the left hemisphere is more capable with tasks that require causal inference. Using Navon’s stimuli, investigators showed that patients with left-sided lesions were slow to identify local targets, and patients with right-sided lesions were slow with global targets, thus demonstrating that the left hemisphere is more adept at representing local information and the right hemisphere is better with global information. The left hemisphere contains what Michael Gazzaniga and Joseph LeDoux have called the interpreter, a system that seeks explanations for internal and external events in order to produce appropriate response behaviors.

The Evolutionary Basis of Hemispheric Specialization So far in this chapter, we have reviewed general principles of hemispheric specialization in humans. Humans, of course, have evolutionary ancestors, so we might expect to find evidence of lateralized functions in other animals. Indeed, this is the case.

Hemispheric Specialization in Nonhumans Due to the central role of language in hemispheric specialization, laterality research has focused primarily on humans. But the evolutionary pressures that underlie hemispheric specialization—the need for unified action, rapid communication, and reduced costs associated with interhemispheric processing—would also be potentially advantageous to other species. It is now clear that hemispheric specialization is not a uniquely human feature (Bradshaw & Rogers, 1993). In birds, almost all of the optic fibers cross at the optic chiasm, ensuring that all of the visual input from each eye projects solely to the contralateral hemisphere. The lack of crossed and uncrossed fibers probably reflects the fact that there is little overlap in the visual fields of birds, owing to the lateral placement of the eyes (Figure 4.35). Moreover, birds lack a corpus callosum, so communication between the visual systems within each hemisphere is limited, and functional asymmetries might result. Several asymmetries are known in birds. Chickens and pigeons are better at categorizing stimuli viewed by the right eye and left hemisphere than by the left eye and right hemisphere. You may wonder what is meant when

Left-eye field of view

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FIGURE 4.35 Visual pathways in birds are completely crossed. This organization indicates that there is little overlap in the regions of space seen by each eye, and thus the visual input to the left hemisphere is independent of the visual input to the right hemisphere. This anatomical segregation would be expected to favor the emergence of hemispheric asymmetries.

a chicken categorizes stimuli. Here is one such category: Edible or not? Chickens are more proficient in discriminating food from nonfood items when stimuli are presented to the right eye, whereas the right hemisphere (left eye) is more adept when they are trained to respond to unique properties like color, size, and shape, or when the task requires them to learn the exact location of a food source. Almost all birds have a communication system: They caw, tweet, and chirp to scare away enemies, mark territory, and lure mates. In many species, the mechanisms of song production depend on structures in the left hemisphere. Fernando Nottebohm of Rockefeller University discovered that sectioning the canary’s hypoglossal nerve in its left hemisphere severely disrupted song production (Nottebohm, 1980). In contrast, righthemisphere lesions had little effect. A similar effect can be found in other bird species, although in some species lesions to either hemisphere can interfere with song production. Nonhuman primates also show differences in hemispheric structure and perhaps function. Old World monkeys and apes have lateral fissures that slope upward in the right hemisphere, similar to the asymmetry found in humans. Whether these anatomical asymmetries are associated with behavioral specializations remains unclear. Unlike humans, however, nonhuman primates do not commonly show a predominance of right-handedness. Individual animals may show a preference for one hand

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or the other, but there is no consistent trend for the right hand to be favored over the left hand, either when making manual gestures or when using tools, except in one case. The great apes appear to use the right hand and arm when making communicative gestures (Meguerditchian et al., 2010). We will discuss this more in Chapter 11, as it suggests the possibility that gestural communication was a forerunner of language. Perceptual studies, however, have provided more provocative indications of asymmetrical functions in nonhuman primates. Like humans, rhesus monkeys are better at tactile discriminations of shape when using the left hand. Even more impressive is that splitbrain monkeys and split-brain humans have similar hemispheric interactions in visual perception tasks. For example, in a face recognition task, the monkeys, like humans, have a right-hemisphere advantage; in a line orientation task, the monkeys share a left-hemisphere advantage. The visual system of monkeys, however, transfers visual information across an intact anterior commissure, but there is no transfer of visual information across the human anterior commissure. In addition, left-hemisphere lesions in the Japanese macaque can impair the animal’s ability to comprehend the vocalizations of conspecifics. Unlike the effects on some aphasic patients, however, this deficit is mild and transient. There is also evidence from split-brain monkeys that unlike humans, their left brain is better at spatial judgments. This observation is tantalizing, because it is consistent with the idea that the evolution of language in the left hemisphere has resulted in the loss of some visuospatial abilities. In summary, like humans, nonhuman species exhibit differences in the function of the two hemispheres. The question remains, how should we interpret these findings? Does the left hemisphere, which specializes in birdsong and human language, reflect a common evolutionary antecedent? If so, this adaptation has an ancient history, because humans and birds have not shared a common ancestor since before the dinosaurs. The hemispheric specialization that occurs in many species may instead reflect a general design principle of the brain.

Modularity In this chapter, we have reviewed general principles of hemispheric specialization in humans. A first step in understanding why these specializations exist is to look at what is known about the structure of the brain and its organizing principles. In Chapter 2 (see the box “How the Brain Works: Billions and Billions”), we briefly touched on the idea that certain “wiring laws” apply to the evolutionary development of the large human brain

(Striedter, 2005). We saw that as the brain grew larger, the proportional connectivity decreases, thus changing the internal structure and resulting in a decrease in overall connectivity. The wiring plan that evolved, which has a high degree of local efficiency and fast communication with the global network, is known as “small-world” architecture (Watts & Strogatz, 1998). This structure is common to many complex systems, that is, systems whose overall behavior can be characterized as more than the sum of their parts. This mode of organization is characterized by many short connections between components, resulting in faster signaling and lower energy requirements. It also has a high level of clustering, which gives the overall system greater tolerance to the failure of individual components or connections. The local networks in the brain are made up of elements (neurons) that are more highly connected to one another than to elements in other networks. This division of circuits into numerous networks both reduces the interdependence of networks and increases their robustness. What’s more, it facilitates behavioral adaptation (Kirschner & Gerhart, 1998), because each network can both function and change its function without affecting the rest of the system. These local specialized networks, which can perform unique functions and can adapt or evolve to external demands, are known as modules. The general concept of modularity is that the components of a system can be categorized according to their functions (Bassett & Gazzaniga, 2011). By reducing constraints on change, the principle of modularity forms the structural basis on which subsystems can evolve and adapt (Wagner et al., 2007) in a highly variable environment. Hemispheric specialization takes that idea a step further and says that cerebral asymmetries in this modular organization must also have adaptive value. Therefore, cerebral asymmetries should not be proposed lightly, and investigators must be sure they are real. For instance, during the 1990s, a popular model of the organization of memory in the brain based on early neuroimaging studies suggested that episodic encoding was predominantly a left hemisphere function and that episodic retrieval was predominantly a right hemisphere function (the model was called HERA, for hemispheric encoding/ retrieval asymmetry). When this model was tested directly with split-brain patients, however, it turned out that each hemisphere was equally efficient at encoding and retrieval (M. Miller et al., 2002). This study showed that apparent asymmetries in memory encoding could be produced by varying the stimuli being encoded. Verbal material was preferentially processed in the participants’ left hemisphere, and facial material

The Evolutionary Basis of Hemispheric Specialization | 155 was preferentially processed in the right—a pattern somewhat reminiscent of the chicken’s and pigeon’s lateralized object discrimination.

Hemispheric Specialization: ADichotomy in Function or Stylishly Different? Laterality researchers continually grapple with appropriate ways to describe asymmetries in the function of the two hemispheres (Allen, 1983; Bradshaw & Nettleton, 1981; Bryden, 1982). While early hypotheses fixed on the stimuli’s properties and the tasks employed, a more recent approach is to look for differences in processing style. This concept suggests that the two hemispheres process information in complementary ways, dividing the workload of processing a stimulus by tackling it differently. From this perspective, the left hemisphere has been described as analytic and sequential, and the right hemisphere is viewed as holistic and parallel. Hemispheric specializations may emerge because certain tasks benefit from one processing style or another. Language, for example, is seen as sequential: We hear speech as a continuous stream that requires rapid dissection and analysis of its component parts. Spatial representations, in contrast, call for not just perceiving the component parts, but seeing them as a coherent whole. The finding that the right hemisphere is more efficient at global processing is consistent with this idea. Although this analytic–holistic dichotomy has intuitive appeal, it is difficult to know whether a particular cognitive task would benefit more from analytic or holistic processing. In many cases, the theoretical interpretation disintegrates into a circular re-description of results. For example, a right-ear advantage exists in the perception of consonants, but no asymmetry is found for vowels; consonants require the sequential, analytic processors of the left hemisphere, and vowel perception entails a more holistic form of processing. Here we have redefined the requirements of processing vowels and consonants according to our theoretical framework, rather than using the data to establish and modify that theoretical framework. With verbal–spatial and analytic–holistic hypotheses, we assume that a single fundamental dichotomy can characterize the differences in function between the two hemispheres. The appeal of “dichotomania” is one of parsimony: The simplest account of hemispheric specialization rests on a single difference. Current dichotomies, however, all have their limitations. It is also reasonable to suppose that a fundamental dichotomy between the two hemispheres is a fiction. Hemispheric asymmetries have been observed in many

task domains: language, motor control, attention, and object recognition. Perhaps specializations are specific to particular task domains and are the consequences of more primitive hemispheric specializations. There need not be a causal connection between hemispheric specialization in motor control (e.g., why people are right- or left-handed) and hemispheric differences in representing language or visuospatial information. Maybe the commonality across task domains is their evolution: As the two hemispheres became segregated, they shared an impetus for the evolution of systems that were non-identical. Asymmetry in how information is processed, represented, and used may be a more efficient and flexible design principle than redundancy across the hemispheres. With a growing demand for cortical space, perhaps the forces of natural selection began to modify one hemisphere but not the other. Because the corpus callosum exchanges information between the hemispheres, mutational events could occur in one lateralized cortical area while leaving the contralateral hemisphere intact, thus continuing to provide the previous cortical function to the entire cognitive system. In short, asymmetrical development allowed for no-cost extensions; cortical capacity could expand by reducing redundancy and extending its space for new cortical zones. Support for this idea is provided by the fascinating work of Galuske and colleagues, which has revealed that differences in the neuronal organization of the left and right Brodmann area 22 are related to the processing of auditory signals associated with human speech (Galuske et al., 2000; Gazzaniga, 2000). The left is specialized for word detection and generation; the right is specialized for melody, pitch, and intensity, which are properties of all auditory communication from bird tweets to monkey calls. The idea of asymmetrical processing also underscores an important point in modern conceptualizations of hemispheric specialization—namely, that the two hemispheres may work in concert to perform a task, even though their contributions may vary widely. There is no need to suppose that some sort of master director decides which hemisphere is needed for a task. While language is predominantly the domain of the left hemisphere, the right hemisphere also might contribute, although the types of representations it derives may not be efficient or capable of certain tasks. In addition, the left hemisphere does not defer to the right hemisphere on visuospatial tasks, but processes this information in a different way. By seeing the brain organized in this way, we begin to realize that much of what we learn from clinical tests of hemispheric specialization tells us more about our tasks rather than the computations performed by each hemisphere. This point is also evident in splitbrain research. With the notable exception of speech

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production, each hemisphere has some competence in every cognitive domain.

Is There a Connection Between Handedness and Left-Hemisphere Language Dominance? With all this talk of laterality, your left hemisphere no doubt is searching for a causal relationship between the predominance of right-handedness and the left hemisphere’s specialization for language. Join the club. Many researchers have tried to establish a causal relationship between the two by pointing out that the dominant role of the left hemisphere in language strongly correlates with handedness. About 96 % of right-handers are left-hemisphere dominant for speech. Most left-handers (60 %), however, are also left-hemisphere dominant for speech (Risse et al., 1997). Because left-handers constitute only 7 % to 8 % of the total population, this means that 96 % of humans, regardless of which hand is dominant, have a left-hemisphere specialization for language. Some theorists point to the need for a single motor center as the critical factor. Although there may be benefits to perceiving information in parallel, that is, it is okay for the input to be asymmetric, our response to these stimuli—the output—must be unified. Imagine what it would be like if your left hemisphere could choose one course of action while your right hemisphere opted for another. What happens when one hemisphere is commanding half your body to sit, and the other hemisphere is telling the other half to vacuum? Our brains may have two halves, but we have only one body. By localizing action planning in a single hemisphere, the brain achieves unification. One hypothesis is that the left hemisphere is specialized for the planning and production of sequential movements. Speech certainly depends on such movements. Our ability to produce speech is the result of many evolutionary changes that include the shape of the vocal tract and articulatory apparatus. These adaptations make it possible for us to communicate, and to do so at phenomenally high rates (think of auctioneers); the official record is 637 words per minute, set on the late-1980s British television show Motormouth. Such competence requires exquisite control of the sequential gestures of the vocal cords, jaw, tongue, and other articulators. The left hemisphere has also been linked to sequential movements in domains that are not involved with speech. For example, left-hemisphere lesions are more likely to cause apraxia—a deficit in motor planning, in which the ability to produce coherent actions is lost, even though the muscles work properly and the person understands and wants to perform an action (see Chapter 8). In addition,

oral movements have left-hemisphere dominance, whether the movements create speech or nonverbal facial gestures. Evidence suggests that facial gestures are more pronounced on the right side of the face, and activation of the right facial muscles occurs more quickly than activation of the corresponding muscles on the left. Time-lapse photography reveals that smiles light up the right side of the face first. Hence, the left hemisphere may have a specialized role in the control of sequential actions, and this role may underlie hemispheric asymmetries in both language and motor functions. Some have theorized that the recursive processing capabilities used by the speech center are available to other left-hemisphere functions, including control of the right hand. With bipedalism, the hands became free to operate independently. This ability is unlike that of our quadruped friends, whose forelimbs and hind limbs are used primarily for locomotion. Here, symmetry is vital for the animal to move in a linear trajectory. If the limbs on one side of the body were longer or stronger than the other, an animal would move in a circle. As our ancestors adopted an upright posture, however, they no longer had to use their hands to move symmetrically. The generative and recursive aspects of an emerging communication system also could have been applied to the way hands manipulated objects, and the lateralization of these properties would have favored the right hand. The favoring of one hand over another would be most evident in tool use. Although nonhuman primates and birds can fashion primitive tools to gain access to foods that are out of reach or encased in hard shells, humans manufacture tools generatively: We design tools to solve an immediate problem, and we also can recombine the parts to create new tools. The wheel, an efficient component of devices for transportation, can be used to extract energy from a flowing river or record information in a compact, easily accessible format. Handedness, then, is most apparent in our use of tools. As an example, right-handers differ only slightly in their ability to use either hand to block balls thrown at them. But when they are asked to catch or throw the balls, the dominant hand has a clear advantage. Or, the situation could have been reversed. The left hemisphere’s dominance in language may be a consequence of an existing specialization in motor control. The asymmetrical use of hands to perform complex actions, including those associated with tool use, may have promoted the development of language. From comparative studies of language, we believe that most sentence forms convey actions; infants issue commands such as “come” or “eat” before they start using adjectives (e.g., “hungry”). If the right hand was being used for many of these actions, there may have been a selective pressure

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HOW THE BRAIN WORKS

To Approach or Withdraw: The Cerebral Tug-of-War It is Friday night, and you are heading to a party at the apartment of a friend of a friend. You arrive and look around: Loud music and swirling bodies move about the living room, and a throng has gathered in the kitchen around a counter laid out with chips and dips. Unfortunately, your friend is nowhere to be seen, and you have yet to recognize a single person among the crowd. Your reaction will depend on a number of factors: how comfortable you feel mingling with strangers, how lively you are feeling tonight, whether a host approaches and introduces you to a few of the guests. Unless you have a flair for flamboyance, you are unlikely to head straight to the dance floor. A more likely response is that you will head for the kitchen and find yourself something to drink. Richard Davidson (1995) of the University of Wisconsin proposed that the fundamental tension for any mobile organism is between approach and withdrawal. Is a stimulus a potential food source to be approached and gobbled up, or a potential predator that must be avoided? Even the most primitive organisms display at least a rudimentary distinction between approach and withdrawal behaviors. The evolution of more complex nervous systems has provided mechanisms to modulate the tension between these two behavioral poles: We might overcome our initial reaction to flee the party, knowing that if we stay we are likely to make a few new friends and have a few good laughs. According to Davidson, this tension involves a delicate interplay between processing within the medial regions of the prefrontal cortex in the right and left cerebral hemispheres. The prefrontal cortex is a major point of convergence in the central nervous system, processing information not only from other cortical regions but also from subcortical regions, especially those involved in emotional processing (see Chapter 10). In Davidson’s theory, these inputs are processed asymmetrically. Left-hemisphere processing is biased to promote approach behaviors; in contrast, right-hemisphere processing is biased to promote withdrawal behaviors. This theory has provided an organizing principle to evaluate the changes in behavior that follow neurological damage. For example, damage to the left frontal lobe can result in severe depression, a state in which the primary symptom is withdrawal and inactivity. Although we might expect depression to be a normal response to brain injury, the opposite profile has been reported in patients with right frontal damage. These patients may appear manic. Damage to the right-hemisphere “withdrawal” system biases the patient to be socially engaging, even when such behaviors are no longer appropriate.

More compelling evidence comes from physiological studies that have looked at the brain’s response to affective, or emotional, stimuli (Gur et al., 1994). By their very nature, positive stimuli are likely to elicit approach, and negative stimuli will elicit withdrawal or avoidance. Thus, depending on its valence, an affective stimulus is likely to engage the two hemispheres differentially. Davidson (1995) tested this idea by taking electroencephalographic (EEG) measurements while participants viewed short video clips that were chosen to evoke either positive (e.g., a puppy playing with flowers) or negative (e.g., a leg being amputated) emotional reactions. The EEG activity during these stimuli was compared to that during a baseline condition in which the participants watched a neutral video segment. As predicted, more neural activity was observed over the left frontal lobe when the participants watched the positive videos in comparison to the negative videos. In contrast, a huge increase in activity over the right frontal lobe was recorded while participants viewed the disturbing video. There are, of course, individual differences in this cerebral tug-of-war between approach and withdrawal. Depression has been linked to an abnormal imbalance favoring neural activity in the right hemisphere. Whether the imbalance preceded or followed the depression remains unclear. More provocative, EEG asymmetries in 3-year-old children are correlated with how well the kids tolerate being separated from their mothers. Children showing higher basal EEG activity in the right hemisphere are more inhibited, staying next to their mother even when surrounded by an array of new toys. Children with higher basal EEG activity in the left hemisphere are quite content to leave their mother to play with the toys. The study of hemispheric asymmetries in emotion is in its infancy. Before the 1990s, physiological studies of emotion generally focused on interactions between the subcortical limbic system and the cortex. In developing his account of cortical differences, Davidson started from a consideration of a marked behavioral dichotomy. What remains to be explored are the computations that might lead to one type of behavior over another, and whether these computations are related to those uncovered in the study of hemispheric specialization in other cognitive domains. In the interim, however, we might cull from this work one strategy to test the next time we find ourselves alone at a party: Start talking to someone, just to get the left hemisphere active. Perhaps the reason why the left hemisphere appears specialized to promote approach behavior is its dominance in language, that most social of all behaviors.

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for the left hemisphere to be more proficient in establishing these symbolic representations. But remember, correlation is not causation. It is also possible (and your left brain is just going to have to get over it) that the mechanisms producing hemispheric specialization in language and motor performance are unrelated. The correlation between these two cardinal signs of hemispheric asymmetry is not perfect. Not only do a small percentage of right-handers exhibit either righthemisphere language or bilateral language, but in at least half of the left-handed population, the left hemisphere is dominant for language. These differences may reflect the fact that handedness is affected at least partly by environmental factors. Children may be encouraged to use one hand over the other, perhaps owing to cultural biases or to parental pressure. Or handedness and language dominance may simply reflect different factors. Fred Previc (1991), a researcher with the U.S. Air Force, proposed an intriguing hypothesis along these lines. According to Previc, the left-hemisphere dominance for language is related primarily to a subtle asymmetry in the skull’s structure. In most individuals, the orofacial bones on the left side of the face are slightly larger—an enlargement that encroaches on middle-ear function and could limit the sensitivity to certain sound frequencies. Previc maintained that this enlargement has a deleterious effect on the projection of auditory information to the right hemisphere, especially in the frequency region that carries most of the critical information for speech. As such, the left hemisphere is favored for phonemic analysis and develops a specialization for language. In contrast to this explanation of hemispheric specialization, Previc (1991) argued that handedness is determined by the position of the fetus during gestation (Figure 4.36). Two thirds of fetuses are oriented with the head downward and the right ear facing the mother’s front. This orientation leads to greater in vitro stimulation of the left utricle, part of the vestibular apparatus in the inner ear that is critical for balance. This asymmetrical stimulation will lead to a more developed vestibular system in the right side of the brain, causing babies to be born with a bias to use the left side of the body for balance and the maintenance of posture. Thus the right side of the body is freed for more exploratory movement, resulting in right-handedness. This still leaves 33 % with reversed symmetry, but only 7 % to 8 % of the population actually is reversed. So other factors, either environmental or biological, likely play a role. According to Previc’s theories, different factors determine language asymmetries and handedness. Current data are too scant for evaluating either mechanism, but they do raise the interesting possibility that many

Right ear faces abdominal wall

FIGURE 4.36 The womb may affect postnatal manual coordination. According to Fred Previc, functional asymmetries in manual coordination are sometimes attributed to the prenatal environment of the fetus. The position of the fetus in the uterus is thought to influence prenatal vestibular experience. Most fetuses are oriented with the right ear facing outward, resulting in a larger vestibular signal in the right hemisphere. At birth, the left side of the body is more stable, freeing the right hand for exploration.

unrelated factors determine patterns of hemispheric specialization. Several genetic models attempt to explain the distribution of handedness among humans. One model states that one gene has two alleles: The D (as in the Latin dextro) allele specifies right-handedness, and the C allele leaves the handedness to chance. In this model, 100 % of DD individuals are right-handed, 75 % of the heterozygotes (CD) are right-handed, and 50 % of CC individuals are right-handed (McManus, 1999). Marian Annett proposed a different model that could also fit with Previc’s theory, in which handedness exists on a spectrum and the alleles are for cerebral dominance rather than for handedness (Annett, 2002). In her model, right-handedness implies left-hemisphere dominance. Her two alleles are the “right shift” allele (RS1) and an ambivalent allele that has no directional shift (RS2). Homozygous individuals, designated RS11, would be strongly right-handed; heterozygous individuals (RS12) would be less strongly right-handed; and the handedness of homozygous (RS2 2) individuals would be up to chance, but still on a spectrum from right- to left-handed, where some would be ambidextrous. Although genes may play a role in handedness or other asymmetries, no genes for handedness have been identified.

Split-Brain Research as a Window into Conscious Experience | 159

TAKE-HOME MESSAGES • Hemispheric specialization is not a unique human feature, though it is most extensive in humans. The evolutionary pressures underlying hemispheric specialization—the need for unified action, rapid communication, and reduced costs associated with interhemispheric processing—exist across species. • In general, many tasks can be performed successfully by either hemisphere, although the two hemispheres may differ in efficiency. • The two hemispheres may work in concert to perform a task, even though their contributions may vary.

Split-Brain Research as a Window into Conscious Experience As we mentioned at the beginning of the chapter, the fundamental mystery presented by split-brain patients remains unsolved; that is, these patients feel no difference in their conscious experience before and after surgery that disconnects their two hemispheres. This essential finding, along with the discovery of the interpreter, specialized to the left hemisphere, may provide a unique window into the true nature of our conscious experience. One astonishing quality of split-brain patients is that they are utterly unaware of their special status. Although they have lost the ability to transfer most information between their cerebral hemispheres, it has no impact on their overall psychological state. For example, it doesn’t bother them that following the callosotomy, they have lost the ability to verbalize what is in their left visual field. It is not because they have been warned that it will occur; they do not even comment that it is occurring. The left hemisphere in these patients doesn’t seem to miss the right hemisphere at all. More than that, the left brain acts as if the right brain had never been there. This finding has major implications for understanding the role of the brain in conscious experience. Perhaps consciousness is not a single, generalized process. Rather, consciousness may be an emergent property, arising out of hundreds or thousands of specialized systems—that is, modules (Gazzaniga, 2011). These specialized neural circuits enable the processing and mental representation of specific aspects of conscious experience. Many of these modules may be connected to some of the other modules, but not to most of them. And these components compete for attention. For instance, the neural

circuits responsible for the itch on your back, the memory of Friday night’s date, the rumblings of your stomach, the feeling of the sun on your cheek, and the paper that you are working on are fighting for attention. From moment to moment, different modules win the competition, and its neural representation is what you are conscious of in that moment. This dynamic, moment-to-moment cacophony of systems comprises our consciousness. Yet, the weird thing is that we don’t experience the chatter going on up there as the battle rages. What emerges is a unified experience in which our consciousness flows smoothly from one thought to the next, comprising a single unified narrative. The interpreter is crafting this narrative. This specialized neural system continually interprets and rationalizes our behavior, emotions, and thoughts after they occur. Remarkably, this view of consciousness is completely dependent on the existence of the specialized modules. If a particular module is impaired or loses its inputs, it alerts the whole system that something is wrong. For example, if the optic nerve is severed, the patient immediately notices that he is blinded. But if the module itself is removed, as in the case of cortical blindness (see Chapter 5), then no warning signal is sent and the specific information processed by that specialized system is no longer acknowledged (out of sight, out of mind—so to speak). This view explains the phenomenon known as anosognosia, in which patients with certain brain lesions are unaware of and deny that they have clearly observable deficits. For instance, one whole side of their body may be paralyzed, yet they deny they have any problems. This model of the physical basis of conscious experience can also explain the behavior of split-brain patients. When the left hemisphere’s interpreter does not receive input from any of the right hemisphere’s modules, then the right hemisphere and any knowledge of the right hemisphere cease to consciously exist. Thus, the splitbrain patient’s speaking left brain never complains about the shortcomings it may be experiencing due to its disconnection from the right brain. It doesn’t know there are any. Some may argue that this is because the right hemisphere contributes little to cognition, but we have seen in this chapter that the right brain is clearly superior at a number of tasks, including part–whole relations, spatial relationships, spatial matching, veridical memory recollections, amodal completion, causal perception, and processing faces. The right hemisphere must contribute to conscious experience when the corpus callosum is intact; yet when severed, the right hemisphere is not missed. This observation is in synch with the idea that our entire conscious experience arises out of the moment-to-moment tussle as an untold number of specialized modules in the brain are vying for attention, while the left hemisphere’s interpreter strings them together in a coherent narrative.

Summary Research on laterality has provided extensive insights into the organization of the human brain. Surgical disconnection of the cerebral hemispheres has produced an extraordinary opportunity to study how perceptual and cognitive processes are distributed and coordinated within the cerebral cortex. We have seen how visual perceptual information, for example, remains strictly lateralized to one hemisphere following callosal section. Tactile-patterned information also remains lateralized, but attentional mechanisms are not divided by separation of the two hemispheres. Taken together, cortical disconnection produces two independent sensory information-processing systems that call upon a common attentional resource system in the carrying out of perceptual tasks. Split-brain studies also have revealed the complex mosaic of mental processes that contribute to human cognition. The two hemispheres do not represent information in an identical manner, as evidenced by the fact that each hemisphere has developed its own set of specialized capacities. In the vast majority of individuals, the left hemisphere

is clearly dominant for language and speech and seems to possess a uniquely human capacity to interpret behavior and to construct theories about the relationship between perceived events and feelings. Right-hemisphere superiority, on the other hand, can be seen in tasks such as facial recognition and attentional monitoring. Both hemispheres are likely to be involved in the performance of any complex task, but each contributes in its specialized manner. Complementary studies on patients with focal brain lesions and on normal participants tested with lateralized stimuli have underscored not only the presence, but the importance, of lateralized processes for cognitive and perceptual tasks. Recent work has moved laterality research toward a more computational account of hemispheric specialization, seeking to explicate the mechanisms underlying many lateralized perceptual phenomena. These theoretical advances have moved the field away from the popular interpretations of cognitive style and have refocused researchers on understanding the computational differences and specializations of cortical regions in the two hemispheres.

Key Terms amobarbital (p. 125) anterior commissure (p. 128) cerebral specialization (p. 132) corpus callosum (p. 128) dichotic listening task (p. 151) functional asymmetry (p. 126)

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handedness (p. 156) heterotopic areas (p. 128) hierarchical structure (p. 144) homotopic areas (p. 126) interpreter (p. 146) module (p. 154)

planum temporale (p. 126) posterior commissure (p. 128) splenium (p. 128) split-brain research (p. 123) Sylvian fissure (p. 125) transcortical (p. 134) Wada test (p. 125)

Thought Questions 1.

What have we learned from over 50 years of split-brain research? What are some of the questions that remain to be answered?

3.

Why are double dissociations diagnostic of cerebral specializations? What pitfalls exist if a conclusion is based on a single dissociation?

2.

What are the strengths of testing patients who have suffered brain lesions? Are there any shortcomings to this research approach? If so, what are they? What are some of the ethical considerations?

4.

Why do you think the human brain evolved cognitive systems that are represented asymmetrically between the cerebral hemispheres? What are the advantages of asymmetrical processing? What are some possible disadvantages?

Suggested Reading Brown, H., & Kosslyn, S. (1993). Cerebral lateralization. Current Opinion in Neurobiology, 3, 183–186.

Gazzaniga, M. S. (2011). Who’s in charge: Free will and the science of the brain. New York: (Ecco) Harper Row.

Gazzaniga, M. S. (2000). Cerebral specialization and interhemispheric communication: Does the corpus callosum enable the human condition? Brain, 123, 1293–1326.

Hellige, J. B. (1993). Hemispheric asymmetry: What’s right and what’s left. Cambridge, MA: Harvard University Press.

Gazzaniga, M. S. (2005). Forty-five years of split brain research and still going strong. Nature Reviews Neuroscience, 6, 653–659.

Hutsler, J., & Galuske, R. A. (2003). Hemispheric asymmetries in cerebral cortical networks. Trends in Neuroscience, 26, 429–435.

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Monet is only an eye, but my God, what an eye! Paul Cezanne

5 chapter

Sensation and Perception

IN HOSPITAL S ACROSS THE COUNTRY, Neurology Grand Rounds is a weekly event. There, staff neurologists, internists, and residents gather to review the most puzzling and unusual cases being treated on the ward. In Portland, Oregon, the head of neurology presented such a case. He was not puzzled about what had caused his patient’s problem. That was clear. The patient, P.T., had suffered OUTLINE a cerebral vascular accident, commonly known as a stroke. In fact, he had Senses, Sensation, and Perception sustained two strokes. The first, suffered 6 years previously, had been a lefthemisphere stroke. The patient had shown a nearly complete recovery from Sensation: Early Perceptual Processing that stroke. P.T. had suffered a second stroke a few months before, however, Audition and the CT scan showed that the damage was in the right hemisphere. This finding was consistent with the patient’s experience of left-sided weakness, Olfaction although the weakness had mostly subsided after a month. Gustation The unusual aspect of P.T.’s case was the collection of symptoms he continued to experience 4 months later. As he tried to resume the daily routines Somatosensation required on his small family farm, P.T. had particular difficulty recognizing Vision familiar places and objects. While working on a stretch of fence, for example, he might look out over the hills and suddenly realize that he did not know the From Sensation to Perception landscape. It was hard for him to pick out individual dairy cows—a matter Deficits in Visual Perception of concern lest he attempt to milk a bull! Disturbing as this was, it was not the worst of his problems. Most troubling of all, he no longer recognized the Multimodal Perception: I See What people around him, including his wife. He had no trouble seeing her and could You’re Sayin’ accurately describe her actions, but when it came to identifying her, he was Perceptual Reorganization at a complete loss. She was completely unrecognizable to him! He knew that her parts—body, legs, arms, and head—formed a person, but P.T. failed to see these parts as belonging to a specific individual. This deficit was not limited to P.T.’s wife; he had the same problem with other members of his family and friends from his small town, a place he had lived for 66 years. A striking feature of P.T.’s impairment was that his inability to recognize objects and people was limited to the visual modality. As soon as his wife spoke, he immediately recognized her voice. Indeed, he claimed that, on hearing her voice, the visual percept of her would “fall into place.” The shape in front of him would suddenly morph into his wife. In a similar fashion, he could recognize specific objects by touching, smelling, or tasting them. 163

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Senses, Sensation, and Perception The overarching reason why you are sitting here reading this book today is that you had ancestors who successfully survived their environment and reproduced. One reason they were able to do this was their ability to sense and perceive things that could be threatening to their survival and then act on those perceptions. Pretty obvious, right? Less obvious is that most of these perceptions and behavioral responses never even reach people’s conscious awareness, and what does reach our awareness is not an exact replica of the stimulus. This latter phenomenon becomes more evident when we are presented with optical illusions (as we see later in the chapter). Perception begins with a stimulus from the environment, such as sound or light, which stimulates one of the sense organs such as the ear or eye. The input from the sound or light wave is transduced into neural activity by the sense organ and sent to the brain for processing. Sensation refers to the early processing that goes on. The mental representation of that original stimulus, which results from the various processing events, whether it accurately reflects the stimulus or not, is called a percept. Thus, perception is the process of constructing the percept. Our senses are our physiological capacities to provide input from the environment to our neurological system. Hence, our sense of sight is our capacity to capture light waves on the retina, convert them into electrical signals, and ship them on for further processing. We tend to give most of the credit for our survival to our sense of sight, but it does not operate alone. For instance, the classic “we don’t have eyes in the back of our head” problem means we can’t see the bear sneaking up behind us. Instead, the rustling of branches or the snap of a twig warns us. We do not see particularly well in the dark either, as many people know after stubbing a toe when groping about to find the light switch. And though the milk may look fine, one sniff tells you to dump it down the drain. Although these examples illustrate the interplay of senses on the conscious level, neuroimaging studies have helped to reveal that extensive interaction takes place between the sensory modalities much earlier in the processing pathways than was previously imagined. In normal perception, all of the senses are critical. Effectively and safely driving a car down a busy highway requires the successful integration of seeing, touch, hearing, and perhaps even smell (warning, for example, that you have been riding the brakes down a hill). Enjoying a meal also involves the interplay of the senses. We cannot enjoy food intensely without smelling its fragrance. The sense of touch is an essential part of our gastronomic experience also, even if we don’t think much about it. It gives us an appreciation for the texture of the food: the

creamy smoothness of whipped cream or the satisfying crunch of an apple. Even visual cues enhance our gustatory experience—a salad of green, red, and orange hues is much more enticing than one that is brown and black. In this chapter, we begin with an overview of sensation and perception and then turn to a description of what is known about the anatomy and function of the individual senses. Next we tackle the issue of how information from our different sensory systems is integrated to produce a coherent representation of the world. We end by discussing the interesting phenomenon of synesthesia—what happens when sensory information is more integrated than is usual.

Sensation: Early Perceptual Processing Shared Processing From Acquisition to Anatomy Before dealing with each sense individually, let’s look at the anatomical and processing features that the sensory systems have in common. Each system begins with some sort of anatomical structure for collecting, filtering, and amplifying information from the environment. For instance, the outer ear, the ear canal, and inner ear concentrate and amplify sound. In vision, the muscles of the eye direct the gaze, the pupil size is adjusted to filter the amount of light, and the cornea and lens refract light to focus it on the retina. Each system has specialized receptor cells that transduce the environmental stimulus, such as sound waves or light waves or chemicals, into neural signals. These neural signals are passed along their specific sensory nerve pathways: the olfactory signals via the olfactory nerve (first cranial nerve); visual signals via the optic nerve (second cranial nerve); auditory signals via the cochlear nerve (also called the auditory nerve, which joins with the vestibular nerve to form the eighth cranial nerve); taste via the facial and glossopharyngeal nerves (seventh and ninth cranial nerves); facial sensation via the trigeminal nerve (fifth cranial nerve); and sensation for the rest of the body via the sensory nerves that synapse in the dorsal roots of the spinal cord. The sensory nerves from the body travel up the spinal cord and enter the brain through the medulla, where the glossopharyngeal and vestibulocochlear nerves also enter. The facial nerve enters the brainstem at the pontomedullary junction. The trigeminal nerve enters at the level of the pons. These nerves all terminate in different parts of the thalamus (Figure 5.1). The optic nerve travels from the eye socket to the optic chiasm, where fibers from the nasal visual fields cross to the opposite side of the brain, and most (not all) of

Sensation: Early Perceptual Processing | 165 Thalamus Postcentral gyrus somatosensory cortex areas S1 and S2

S1 S2

Touch

Taste

Smell

Vision Hearing

FIGURE 5.1 Major sensory regions of the cerebral cortex.

the newly combined fibers terminate in the thalamus. From the thalamus, neural connections from each of these pathways travel first to what are known as primary sensory cortex, and then to secondary sensory cortex (Figure 5.1). The olfactory nerve is a bit of a rogue. It is the shortest cranial nerve and follows a different course. It terminates in the olfactory bulb, and axons extending from here course directly to the primary and secondary olfactory cortices without going through the brainstem or the thalamus.

and thus, can see ultraviolet light (Figure 5.2b, right). Some bird species actually exhibit sexual dichromatism (the male and female have different coloration) that is not visible to humans. Similar range differences are found in audition. We are reminded of this when we blow a dog whistle (invented by Francis Galton, Charles Darwin’s cousin). We immediately have the dog’s attention, but we cannot hear the high-pitched sound ourselves. Dogs can hear sound-wave frequencies of up to about 60 kilohertz (kHz), but we hear only sounds below about 20 kHz. Although a dog has better night vision than we do, we see more colors. Dogs cannot see the red–green spectrum. As limited as our receptor cells may be, we do respond to a wide range of stimulus intensities. The threshold stimulus value is the minimum stimulus that will activate a percept.

Adaptation Adaptation refers to how sensory systems stay fine-tuned. It is the adjusting of the sensitivity of the sensory system to the current environment and to important changes in the environment. You will come to see that perception is mainly concerned with changes in sensation. This makes good survival sense. Adaptation happens quickly in the olfactory system. You smell the baking bread when you

Receptors Share Responses to Stimuli Across the senses, receptor cells share a few general properties. Receptor cells are limited in the range of stimuli that they respond to, and as part of this limitation, their capability to transmit information has only a certain degree of precision. Receptor cells do not become active until the stimulus exceeds some minimum intensity level. They are not fixed entities, but rather adapt as the environment changes.

a

Range Each sensory modality responds to a limited range of stimuli. Most people’s impression is that human color vision is unlimited. However, there are many colors, or parts of the electromagnetic spectrum, that we cannot see (Figure 5.2). Our vision is limited to a small region of this spectrum, wavelengths of light in the range of 400 to 700 nanometers (nm). Individual receptor cells respond to just a portion of this range. This range is not the same for all species. For example, birds and insects have receptors that are sensitive to shorter wavelengths

b FIGURE 5.2 Vision and light. (a) The electromagnetic spectrum. The small, colored section in the center indicates the part of the spectrum that is visible to the human eye. (b) The visible region of the electromagnetic spectrum varies across species. An evening primrose as seen by humans (left) and bees (right). Bees perceive the ultraviolet part of the spectrum.

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ANATOMICAL ORIENTATION

Anatomy of the senses Primary somatosensory cortex Secondary somatosensory areas

Primary auditory cortex Primary visual cortex

Secondary visual areas Secondary olfactory area

Secondary auditory areas

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Primary olfactory cortex Sensory inputs about taste, touch, smell, hearing, and seeing travel to specific regions of the brain for initial processing.

walk into the bakery, but the fragrance seems to evaporate quickly. Our auditory system also adapts rather quickly. When we first turn the key to start a car, the sound waves from the motor hit our ears, activating sensory neurons. But this activity soon stops, even though the stimulus continues as we drive along the highway. Some neurons continue to fire as long as the stimulus continues, but their rate of firing slows down: the longer the stimulus continues, the less frequent the action potentials are. The noise of the computer drops into the background, and we have “adapted” to it.

Visual system adaptation also occurs for changes in the light intensity in the environment. We frequently move between areas with different light intensities, for instance, when walking from a shaded area into the bright sunlight. It takes some time for the eyes to reset to the ambient light conditions, especially when going from bright light into darkness. When you go camping for the first time with veteran campers, one of the first things you are going to be told is not to shine your flashlight into someone’s eyes. It would take about 20–30 minutes for that person to regain

Audition | 167 her “night vision,” that is, to regain sensitivity to the low level of ambient light after being exposed to the bright light. We discuss how this works later, in the Vision section.

everything that is in front of you, although it has all been recorded on your retina.

Connective Similarities Most people typically think Acuity Our sensory systems are tuned to respond to different sources of information in the environment. Light activates receptors in the retina, pressure waves produce mechanical and electrical changes in the eardrum, and odor molecules are absorbed by receptors in the nose. How good we are at distinguishing among stimuli within a sensory modality, or what we would call acuity, depends on a couple of factors. One is simply the design of the stimulus collection system. Dogs can adjust the position of their two ears independently to better capture sound waves. This design contributes to their ability to hear sounds that are up to four times farther away than humans are capable of hearing. Another factor is the number and distribution of the receptors. For instance, for touch, we have many more receptors on our fingers than we do on our back; thus, we can discern stimuli better with our fingers. Our visual acuity is better than that of most animals, but not better than an eagle. Our acuity is best in the center of our visual field, because the central region of the retina, the fovea, is packed with photoreceptors. The farther away from the fovea, the fewer the receptors. The same is true for the eagle, but he has two foveas. In general, if a sensory system devotes more receptors to certain types of information (e.g., as in the sensory receptors of the hands), there is a corresponding increase in cortical representation of that information (see, for example, Figure 5.16). This finding is interesting, because many creatures carry out exquisite perception without a cortex. So what is our cortex doing with all of the sensory information? The expanded sensory capabilities in humans, and mammals in general, are probably not for better sensation per se; rather, they allow that information to support flexible behavior, due to greatly increased memory capacity and pathways linking that information to our action and attention systems.

Sensory Stimuli Share an Uncertain Fate The physical stimulus is transduced into neural activity (i.e., electrochemical signals) by the receptors and sent through subcortical and cortical regions of the brain to be processed. Sometimes a stimulus may produce subjective sensory awareness. When that happens, the stimulus is not the only factor contributing to the end product. Each level of processing—including attention, memory, and emotional systems—contributes as well. Even with all of this activity going on, most of the sensory stimulation never reaches the level of consciousness. No doubt if you close your eyes right now, you will not be able to describe

of sensory processing as working in one direction; that is, information moves from the sensor organs to the brain. Neural activity, however, is really a two-way street. At all levels of the sensory pathways, neural connections are going in both directions. This feature is especially pronounced at the interface between the subcortex and cortex. Sensory signals from the visual, auditory, somatosensory, and gustatory (taste) systems all synapse within the thalamus before projecting onto specific regions within the cortex. The visual pathway passes through the lateral geniculate nucleus (LGN) of the thalamus, the auditory system through the medial geniculate nucleus (MGN), the somatic pathway through the ventral posterior nuclear complex and the gustatory pathway through the ventral posteromedial nucleus. Just exactly what is going on in the thalamus is unclear. It appears to be more than just a relay station. Not only are there projections from these nuclei to the cortex, but the thalamic nuclei are interconnected, providing an opportunity for multisensory integration, an issue we turn to later in the chapter. The thalamus also receives descending, or feedback, connections from primary sensory regions of the cortex as well as other areas of the cortex, such as the frontal lobe. These connections appear to provide a way for the cortex to control, to some degree, the flow of information from the sensory systems (see Chapter 7). Now that we have a general idea of what is similar about the anatomy of the various sensory systems and processing of sensory stimuli, let’s take a closer look at the individual sensory systems.

Audition Imagine you are out walking to your car late at night, and you hear a rustling sound. Your ears (and heart!) are working on overdrive, trying to determine what is making the sound (or more troubling, who) and where the sound is coming from. Is it merely a tree branch blowing in the breeze, or is someone sneaking up behind you? The sense of hearing, or audition, plays an important role in our daily lives. Sounds can be essential for survival— we want to avoid possible attacks and injury—but audition also is fundamental for communication. How does the brain process sound? What happens as sound waves enter the ear? And how does our brain interpret these signals? More specifically, how does the nervous system figure out the what and the where of sound sources?

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Neural Pathways of Audition Figure 5.3 presents an overview of the auditory pathways. The complex structures of the inner ear provide the mechanisms for transforming sounds (variations in sound pressure) into neural signals. This is how hearing works: Sound waves arriving at the ear enter the auditory canal. Within the canal, the sound waves are amplified, similar to what happens when you honk your car’s horn in a tunnel. The waves travel to the far end of the canal, where they hit the tympanic membrane, or eardrum, and make it vibrate. These low-pressure vibrations then travel through the air-filled middle ear and rattle three tiny bones, the malleus, incus, and stapes, which cause a second membrane, the oval window, to vibrate. The oval window is the “door” to the fluid-filled cochlea, the critical auditory structure of the inner ear. Within the cochlea are tiny hair cells located along the inner surface of the basilar membrane. The hair cells are the sensory receptors of the auditory system. Hair cells are composed of up to 200 tiny filaments known as stereocilia that float in the fluid. The vibrations at the oval window produce tiny waves in the fluid that move the basilar membrane, deflecting the stereocilia. The location of a hair cell on the basilar membrane determines its frequency tuning, the sound frequency that it responds to. This is because the thickness (and thus, the stiffness) of the basilar membrane varies along its length from the oval window to the apex of the cochlea. The thickness constrains how the membrane will move in response to the fluid waves. Near the oval window, the membrane is thick and stiff. Hair cells attached here can respond to high-frequency vibrations in the waves. At the other end, the apex of the cochlea, the membrane is thinner

Malleus Stapes

Oval window

and less stiff. Hair cells attached here will respond only to low frequencies. This spatial arrangement of the sound receptors is known as tonotopy, and the arrangement of the hair cells along the cochlear canal form a tonotopic map. Thus, even at this early stage of the auditory system, information about the sound source can be discerned. The hair cells act as mechanoreceptors. When deflected by the membrane, mechanically gated ion channels open in the hair cells, allowing positively charged ions of potassium and calcium to flow into the cell. If the cell is sufficiently depolarized, it will release transmitter into a synapse between the base of the hair cell and an afferent nerve fiber. In this way, a mechanical event, the deflections of the hair cells, is converted into a neural signal (Figure 5.4). Natural sounds like music or speech are made up of complex frequencies. Thus, a natural sound will activate a broad range of hair cells. Although we can hear sounds up to 20,000 hertz (Hz), our auditory system is most sensitive to sounds in the range of 1000 to 4000 Hz, a range that carries much of the information critical for human communication, such as speech or the cries of a hungry infant. Other species have sensitivity to very different frequencies. Elephants can hear very low-frequency sounds, allowing them to communicate

Primary auditory cortex

Primary auditory cortex Medial geniculate nucleus of the thalamus

Medial geniculate nucleus of the thalamus

Cochlea Hair cells

Inferior colliculus Inferior colliculus

Dorsal cochlear nucleus Auditory nerve Tympanic membrane

Incus

Ventral cochlear nucleus

Auditory nerve

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FIGURE 5.3 Overview of the auditory pathway. The hair cells of the cochlea are the primary receptors. The output from the auditory nerve projects tothe cochlear nuclei in the brainstem. Ascending fibers reach the auditory cortex following synapses in the inferior colliculus and medial geniculate nucleus.

Superior olivary nucleus

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Audition | 169

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FIGURE 5.4 Transduction of sound waves along the cochlea. The cochlea is unrolled to show how the sensitivity to different frequencies varies with distance from the stapes.

over long distances (since such sounds are only slowly distorted by distance); mice communicate at frequencies well outside our hearing system. These speciesspecific differences likely reflect evolutionary pressures that arose from the capabilities of different animals to produce sounds. Our speech apparatus has evolved to produce changes in sound frequencies in the range of our highest sensitivity. The auditory system contains several synapses between the hair cells and the cortex. The cochlear nerve, also called the auditory nerve, projects to the cochlear nucleus in the medulla. Axons from this nucleus travel up to the pons and split to innervate the left and right olivary nucleus, providing the first point within the auditory pathways where information is shared from both ears. Axons from the cochlear and olivary nuclei project to the inferior colliculus, higher up in the midbrain. At this stage, the auditory signals can access motor structures; for example, motor neurons in the colliculus can orient the head toward a sound. Some of the axons coursing through the pons branch off to the nucleus of the lateral lemniscus in the midbrain, where another important

characteristic of sound, timing, is processed. From the midbrain, auditory information ascends to the MGN in the thalamus, which in turn projects to the primary auditory cortex (A1) in the superior part of the temporal lobe. Neurons throughout the auditory pathway continue to have frequency tuning and maintain their tonotopic arrangement as they travel up to the cortex. As described in Chapter 2 (p. 56), the primary auditory cortex contains a tonotopic map, an orderly correspondence between the location of the neurons and their specific frequency tuning. Cells in the rostral part of A1 tend to be responsive to low-frequency sounds; cells in the caudal part of A1 are more responsive to high-frequency sounds. The tonotopic organization is evident in studies using single-cell recording methods, and thanks to the resolution provided by fMRI, it can also be seen in humans (Figure 5.5). Tonotopic maps are also found in secondary auditory areas of the cortex. As Figure 5.6 shows, the tuning curves for auditory cells can be quite broad. The finding that individual cells do not give precise frequency information but provide only coarse coding may seem puzzling, because animals can differentiate between very small differences in sound frequencies. Interestingly, the tuning of individual neurons becomes sharper as we move through the auditory system. A neuron in the cat’s cochlear nucleus that responds maximally to a pure tone of 5000 Hz may also respond to tones ranging from 2000 to 10,000 Hz. A comparable neuron in the cat auditory cortex responds to a much narrower range of frequencies. The same principle is observed in humans. In one study, electrodes were placed in the auditory cortex of epileptic patients to monitor for seizure activity (Bitterman et al., 2008). Individual cells were exquisitely tuned, showing a strong response to, say, a tone at 1010 Hz but no response, or even a slight inhibition to tones just 20 Hz different. This fine resolution is essential for making the precise discriminations for perceiving sounds, including speech. Indeed, it appears that human auditory tuning is sharper than that of all other species except for the bat. While A1 is, at a gross level, tonotopically organized, more recent studies using high-resolution imaging methods in the mouse suggest that, at a finer level of resolution, organization may be much more messy. At this level, adjacent cells frequently show very different tuning. Thus, there is a large-scale tonotopic organization but with considerable heterogeneity at the local level (Bandyopadhyay et al., 2010; Rothchild et al., 2010). This mixture may reflect the fact that natural sounds contain information across a broad range of frequencies and that the local organization arises from experience with these sounds.

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Response to highintensity sound

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FIGURE 5.6 Frequency-dependent receptive fields for a cell in the auditory nerve of the squirrel monkey. This cell is maximally sensitive to a sound of 1600 Hz, and the firing rate falls off rapidly for either lower- or higher-frequency sounds. The cell is also sensitive to intensity differences, with stronger responses to louder sounds. Other cells in the auditory nerve would show tuning for different frequencies.

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Sensitivity to lower frequencies FIGURE 5.5 The auditory cortex and tonotopic maps. (a) The primary auditory cortex is located in the superior portion of the temporal lobe (left and right hemispheres), with the majority of the region buried in the lateral sulcus on the transverse temporal gyrus and extending onto the superior temporal gyrus. (b) A flat map representation of primary and secondary auditory regions. Multiple tonotopic maps are evident, with the clearest organization evident in primary auditory cortex.

Computational Goals in Audition Frequency data are essential for deciphering a sound. Sound-producing objects have unique resonant properties that provide a characteristic signature. The same

note played on a clarinet and a trumpet will sound differently, because the resonant properties of each instrument will produce considerable differences in the note’s harmonic structure. Yet, we are able to identify a “G” from different instruments as the same note. This is because the notes share the same base frequency. In a similar way, we produce our range of speech sounds by varying the resonant properties of the vocal tract. Movements of our lips, tongue, and jaw change the frequency content of the acoustic stream produced during speech. Frequency variation is essential for a listener to identify words or music. Auditory perception does not merely identify the content of an acoustic stimulus. A second important function of audition is to localize sounds in space. Consider the bat, which hunts by echolocation. High-pitched sounds are emitted by the bat and bounce back, as echoes from the environment. From these echoes, the bat’s brain creates an auditory image of the environment and the objects within it—preferably a tasty moth. But knowing that a moth (“what”) is present will not lead to a successful hunt. The bat also has to determine the moth’s precise location (“where”). Some very elegant work in the neuroscience of audition has focused on the “where” problem. In solving the “where” problem, the auditory system relies on integrating information from the two ears. In developing animal models to study auditory perception, neuroscientists select animals with well-developed hearing. A favorite species for this work has been the

Audition | 171 barn owl, a nocturnal creature. Barn owls have excellent scotopia (night vision), which guides them to their prey. Barn owls, however, also must use an exquisitely tuned sense of hearing to locate food, because visual information can be unreliable at night. The low levels of illumination provided by the moon and stars fluctuate with the lunar cycle and clouds. Sound, such as the patter of a mouse scurrying across a field, offers a more reliable stimulus. Indeed, barn owls have little trouble finding prey in a completely dark laboratory. Barn owls rely on two cues to localize sounds: the difference in when a sound reaches each of the two ears, the interaural time, and the difference in the sound’s intensity at the two ears. Both cues exist because the sound reaching two ears is not identical. Unless the sound source is directly parallel to the head’s orientation, the sound will reach one ear before the other. Moreover, because the intensity of a sound wave becomes attenuated over time, the magnitude of the signal at the two ears will not be identical. The time and intensity differences are minuscule. For example, if the stimulus is located at a 45° angle to the line of sight, the interaural time difference will be approximately 1/10,000 of a second. The intensity differences resulting from sound attenuation are even smaller—indistinguishable from variations due to “noise.” However, these small differences are amplified by a unique asymmetry of owl anatomy: The left ear is higher than eye level and points downward, and the right ear is lower than eye level and points upward. Because of this asymmetry, sounds coming from below are louder in the left ear than the right. Humans do not have this asymmetry, but the complex structure of the human outer ear, or pinna, amplifies the intensity difference between a sound heard at the two ears (Figure 5.7).

a

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Interaural time and intensity differences provide independent cues for sound localization. To show this, researchers use little owl headphones. Stimuli are presented over headphones, and the owl is trained to turn its head in the perceived direction of the sound. The headphones allow the experimenter to manipulate each cue separately. When amplitude is held constant, asynchronies in presentation times prompt the owl to shift its head in the horizontal plane. Variations in amplitude produce vertical head movements. Combining the two cues by fusing the inputs from the two ears provides the owl with a complete representation of three-dimensional space. If one ear is plugged, the owl’s response indicates that a sound has been detected, but it cannot localize the source. Mark Konishi of the California Institute of Technology has provided a well-specified neural model of how neurons in the brainstem of the owl code interaural time differences by operating as coincidence detectors (M. Konishi, 1993). To be activated, these neurons must simultaneously receive input from each ear. In computer science terms, these neurons act as AND operators. An input from either ear alone or in succession is not sufficient; the neurons will fire only if an input arrives at the same time from both ears. To see how this model works, look at Figure 5.8. In Figure 5.8a, the sound source is directly in front of the animal. In this situation the coincidence detector in the middle is activated, because the stimulus arrives at each ear at the same time. In Figure 5.8b, the sound source is to the animal’s left. This gives the axon from the left ear a slight head start. Simultaneous activation now occurs in a coincidence detector to the left of center. This simple arrangement provides the owl with a complete representation of the horizontal position of the sound source.

c

FIGURE 5.7 Variation in pinnae. The shape of the pinnae help filter sounds and can amplify differences in the stimulus at the two ears. Considerable variation is seen across species. (a) Great Horned Owl, (b) Fennec Fox, and (c) human.

172 | CHAPTER 5

Sensation and Perception Sound source Sound source

Right ear

Left ear

Relay station in brain

Delay line

Coincidence detector a

b FIGURE 5.8 Slight asymmetries in the arrival times at the two ears can be used to locate the lateral position of a stimulus. (a) When the sound source is directly in front of the owl, the stimulus will reach the two ears at the same time. As activation is transmitted across the delay lines, the coincidence detector representing the central location will be activated simultaneously from both ears. (b) When the sound source is located to the left, the sound reaches the left ear first. Now a coincidence detector offset to the opposite side receives simultaneous activation from the two ears.

A different coding scheme represents interaural intensities. For this stimulus dimension, the neural code is based on the input’s firing rate. The stronger the input signal, the more strongly the cell fires. Neurons sum the combined intensity signals from both ears to pinpoint the vertical position of the source. In Konishi’s model, the problem of sound localization by the barn owl is solved at the level of the brainstem. To date, this theory has not explained higher stages of processing, such as in the auditory cortex. Perhaps cortical processing is essential for converting location information into action. The owl does not want to attack every sound it hears; it must decide if the sound is generated by potential prey. Another way of thinking about this is to reconsider the issues surrounding the computational goals of audition. Konishi’s brainstem system provides the owl with a way to solve “where” problems but has not addressed the “what” question. The owl needs a more detailed analysis of the sound frequencies to determine whether a stimulus results from the movement of a mouse or a deer.

TAKE-HOME MESSAGES ■

Signal transduction from sound wave to neuronal signal begins at the eardrums. Sound waves disturb the hair cells. This mechanical input is transformed into a neural

output at the cochlea. Signals are processed in the hair cells and basilar membrane of the cochlea. The cochlea sends its information in the form of neuronal signals to the inferior colliculus and the cochlear nucleus. Information then travels to the medial geniculate nucleus of the thalamus and on to the primary auditory cortex. Neurons throughout the auditory pathway maintain their tonotopic arrangement as they travel up to the cortex, but the tight organization is less apparent in the auditory cortices A1 and A2 when viewed with high-resolution methods. Sound localization is aided by the processing of differences in interaural time and interaural sound intensity, which are each coded separately in the brain.

Olfaction We have the greatest awareness of our senses of sight, sound, taste, and touch. Yet the more primitive sense of smell is, in many ways, equally essential for our survival. Although the baleen whale probably does not smell the tons of plankton it ingests, the sense of smell is essential for terrestrial mammals, helping them to recognize foods that are nutritious and safe. Olfaction may have evolved primarily as a mechanism for evaluating whether a potential food is edible, but it serves other important roles as well—for instance, in avoiding hazards, such as fire

Olfaction | 173 or airborne toxins. Olfaction also plays an important role in social communication. Pheromones are excreted or secreted chemicals perceived by the olfactory system that trigger a social response in another individual of the same species. Pheromones are well documented in some insects, reptiles, and mammals. It also appears that they play an important role in human social interactions. Odors generated by women appear to vary across the menstrual cycle, and we are all familiar with the strong smells generated by people coming back from a long run. The physiological responses to such smells may be triggered by pheromones. To date, however, no compounds or receptors have been identified in humans. Before discussing the functions of olfaction, let’s review the neural pathways of the brain that respond to odors.

Neural Pathways of Olfaction Smell is the sensory experience that results from the transduction of neural signals triggered by odor molecules, or odorants. These molecules enter the nasal cavity, either during the course of normal breathing or when we sniff. They will also flow into the nose passively, because air pressure in the nasal cavity is typically lower than in the outside environment, creating a pressure gradient. Odorants can also enter the system through the mouth, traveling back up into the nasal cavity (e.g., during consumption of food). How olfactory receptors actually “read” odor molecules is unknown. One popular hypothesis is that odorants attach to odor receptors, which are embedded in

the mucous membrane of the roof of the nasal cavity, called the olfactory epithelium. There are over 1,000 types of receptors, and most of these respond to only a limited number of odorants, though a single odorant can bind to more than one type of receptor. Another hypothesis is that the molecular vibrations of groups of odorant molecules contribute to odor recognition (Franco et al., 2011; Turin, 1996). This model predicts that odorants with similar vibrational spectra should elicit similar olfactory responses, and it explains why similarly shaped molecules, but with dissimilar vibrations, have very different fragrances. For example, alcohols and thiols have almost exactly the same structure, but alcohols have a fragrance of, well, alcohol, and thiols smell like rotten eggs. Figure 5.9 details the olfactory pathway. The olfactory receptor is called a bipolar neuron because appendages extend from opposite sides of its cell body. When an odorant triggers the neuron, whether by shape or vibration, a signal is sent to the neurons in the olfactory bulbs, called the glomeruli. Tremendous convergence and divergence take place in the olfactory bulb. One bipolar neuron may activate over 8,000 glomeruli, and each glomerulus, in turn, receives input from up to 750 receptors. The axons from the glomeruli then exit laterally from the olfactory bulb, forming the olfactory nerve. Their destination is the primary olfactory cortex, or pyriform cortex, located at the ventral junction of the frontal and temporal cortices. The olfactory pathway to the brain is unique in two ways. First, most of the axons of the olfactory nerve project to the ipsilateral cortex. Only a small number cross over to

Orbitofrontal cortex (secondary olfactory area) Glomerulus

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Axons forming olfactory nerve

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FIGURE 5.9 Olfaction. The olfactory receptors lie within the nasal cavity, where they interact directly with odorants. The receptors then send information to the glomeruli in the olfactory bulb, the axons of which form the olfactory nerve that relays information to the primary olfactory cortex. The orbitofrontal cortex is a secondary olfactory processing area.

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FIGURE 5.10 Sniffing and smelling. (a) This special device was constructed to deliver controlled odors during fMRI scanning. (b, top) Regions activated during sniffing. The circled region includes the primary olfactory cortex and a posteromedial region of the orbitofrontal cortex. (b, bottom) Regions more active during sniffing when an odor was present compared to when the odor was absent.

innervate the contralateral hemisphere. Second, unlike the other sensory nerves, the olfactory nerve arrives at the primary olfactory cortex without going through the thalamus. The primary olfactory cortex projects to a secondary olfactory area within the orbitofrontal cortex, as well as making connections with other brain regions including the thalamus, hypothalamus, hippocampus, and amygdala. With these wide-ranging connections, it appears that odor cues influence autonomic behavior, attention, memory, and emotions—something that we all know from experience.

The Role of Sniffing in Olfactory Perception Olfaction has gotten short shrift from cognitive neuroscientists. This neglect reflects, in part, our failure to appreciate the importance of olfaction in people’s lives: We have handed the sniffing crown over to bloodhounds and their ilk. In addition, some thorny technical challenges must be overcome to apply tools such as fMRI to study the human olfactory system. First is the problem of delivering odors to a participant in a controlled manner (Figure 5.10a). Nonmagnetic systems must be constructed to allow the odorized air to be directed at the participant’s nostrils while he is in the fMRI magnet. Second, it is hard to determine when an odor is no longer present. The chemicals that carry the odor can linger in the air for a long time. Third, although some odors overwhelm our senses, most are quite subtle, requiring exploration through the act of sniffing to detect and identify. Whereas it is almost impossible to ignore a sound, we can exert considerable control over the intensity of our olfactory experience.

Noam Sobel of the Weizmann Institute in Israel developed methods to overcome these challenges, conducting neuroimaging studies of olfaction that have revealed an intimate relationship between smelling and sniffing (Mainland & Sobel, 2006; Sobel et al., 1998). Participants were scanned while being exposed to either nonodorized, clean air or one of two chemicals: vanillin or decanoic acid. The former has a fragrance like vanilla, the latter, like crayons. The odor-absent and odor-present conditions alternated every 40 seconds. Throughout the scanning session, the instruction, “Sniff and respond, is there an odor?” was presented every 8 seconds. In this manner, the researchers sought to identify areas in which brain activity was correlated with sniffing versus smelling (Figure 5.10b). Surprisingly, smelling failed to produce consistent activation in the primary olfactory cortex. Instead, the presence of the odor produced a consistent increase in the fMRI response in lateral parts of the orbitofrontal cortex, a region typically thought to be a secondary olfactory area. Activity in the primary olfactory cortex was closely linked to the rate of sniffing. Each time the person took a sniff, the fMRI signal increased regardless of whether the odor was present. These results seemed quite puzzling and suggested that the primary olfactory cortex might be more a part of the motor system for olfaction. Upon further study, however, the lack of activation in the primary olfactory cortex became clear. Neurophysiological studies of the primary olfactory cortex in the rat had shown that these neurons habituate (adapt) quickly. It was suggested that perhaps the primary olfactory cortex lacks a smell-related response because the hemodynamic response measured by fMRI exhibits a similar habituation. To test this idea, Sobel’s group modeled the fMRI signal by assuming a sharp increase followed by an

Olfaction | 175 extended drop after the presentation of an odor—an elegant example of how single-cell results can be used to interpret imaging data. When analyzed in this manner, the hemodynamic response in the primary olfactory cortex was found to be related to smell as well as to sniffing. These results suggest that the role of the primary olfactory cortex might be essential for detecting a change in the external odor and that the secondary olfactory cortex plays a critical role in identifying the odor itself. Each sniff represents an active sampling of the olfactory environment, and the primary olfactory cortex plays a critical role in determining if a new odor is present.

One Nose, Two Odors The importance of sniffing for olfactory perception is underscored by the fact that our ability to smell is continually being modulated by changes in the size of the nasal passages. In fact, the two nostrils appear to switch back and forth—one is larger than the other for a number of hours, and then the reverse. These changes have a profound effect on how smell is processed (Figure 5.11). Why might the nose behave this way?

The olfactory percept depends not only on how intense the odor is but also on how efficiently we sample it (Mozell et al., 1991). The presence of two nostrils of slightly different sizes provides the brain with slightly different images of the olfactory environment. To test the importance of this asymmetry, Sobel monitored which nostril was allowing high airflow and which nostril was allowing low airflow, while presenting odors with both high and low absorption rates to each nostril. As predicted (see Figure 5.11), when sniffed through the high-airflow nostril, the odorant with a high absorption rate was judged to be more intense compared to when the same odorant was presented to the lowairflow nostril. The opposite was true for the odorant with a low absorption rate; here, the odor with a low rate of absorption was judged to be more intense when sniffed through the low-airflow nostril. Some of the participants were monitored when the flow rate of their nostrils reversed. The perception of the odorant presented to the same nostril reversed with the change in airflow. As we saw in Chapter 4, asymmetrical representations are the rule in human cognition, perhaps providing

Olfactory epithelium with layer of mucosa

Nasal cavity

Direction of airflow Nostril Low flow of air entering via smaller nostril

High flow of air entering via larger nostril

Odorant with high rate of absorption Small neuronal response

Large neuronal response

Large neuronal response

Small neuronal response

Odorant with low rate of absorption

FIGURE 5.11 Human nostrils have asymmetric flow rates. Although the same odorants enter each nostril, the response across the epithelium will be different for the two nostrils because of variation in flow rates. One nostril always has a greater input airflow than the other, and the nostrils switch between the two rates every few hours. This system of having one lowflow and one high-flow nostril has evolved to give the nose optimal accuracy in perceiving odorants that have both high and low rates of absorption.

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a more efficient manner of processing complex information. With the ancient sense of olfaction, this asymmetry appears to be introduced at the peripheral level by modulation of the rate of airflow through the nostrils.

TAKE-HOME MESSAGES ■

Signal transduction from odorant to neuronal signal begins when the odorant attaches to an odor receptor in the olfactory epithelium. The signal is then sent to the olfactory bulb through the olfactory nerve, which projects to the primary olfactory cortex. Signals are also relayed to the orbitofrontal cortex, a secondary olfactory processing area. The primary olfactory cortex is important for detecting a change in external odor, and the secondary olfactory cortex is important for identifying the smell itself. Similar to the importance of sampling sound from two ears, we use our two nostrils to obtain different olfactory samples, varying the rate of airflow through each nostril and thus altering the rate of absorption. The olfactory pathway is the only sensory pathway that does not send information to the thalamus.

Gustation The sense of taste depends greatly on the sense of smell. Indeed, the two senses are often grouped together because they both begin with a chemical stimulus. Because these two senses interpret the environment by discriminating between different chemicals, they are referred to as the chemical senses.

Neural Pathways of Gustation Gustation begins with the tongue. Strewn across the surface of the tongue in specific locations are different types of papillae, the little bumps you can feel on the surface. Papillae serve multiple functions. Some are concerned with gustation, others with sensation, and some with the secretion of lingual lipase, an enzyme that helps break down fats. The papillae in the anterior region and along the sides of the tongue contains several taste buds; those types found predominantly in the center of the tongue do not have taste buds. Taste pores are the conduits that lead from the surface of the tongue to the taste buds. Each taste bud contains many taste cells (Figure 5.12). Taste buds are also found in the cheeks and parts of the roof of the mouth. There are five basic tastes: salty, sour, bitter, sweet, and umami. Umami is the savory taste you experience when you eat steak or other protein-rich substances.

Sensory transduction in the gustatory system begins when a food molecule, or tastant, stimulates a receptor in a taste cell and causes the receptor to depolarize (Figure 5.12). Each of the basic taste sensations has a different form of chemical signal transduction. For example, the experience of a salty taste begins when the salt molecule (NaCl) breaks down into Na+ and Cl−, and the Na+ ion is absorbed by a taste receptor, leading the cell to depolarize. Other taste transduction pathways, such as sweet carbohydrate tastants, are more complex, involving receptor binding that does not lead directly to depolarization. Rather, the presence of certain tastants will initiate a cascade of chemical “messengers” that eventually leads to cellular depolarization. Synapsing with the taste cells in the taste buds are bipolar neurons. Their axons form the chorda tympani nerve. The chorda tympani nerve joins other fibers to form the facial nerve (the 7th cranial nerve). This nerve projects to the gustatory nucleus, located in the rostral region of the nucleus of the solitary tract in the brainstem. Meanwhile, the caudal region of the solitary nucleus receives sensory neurons from the gastrointestinal tract. The integration of information at this level can provide a rapid reaction. For example, you might gag if you taste something that is “off,” a strong signal that the food should be avoided. The next synapse in the gustatory system is on the ventral posterior medial nucleus (VPM) of the thalamus. Axons from the VPM synapse in the primary gustatory cortex. This is a region in the insula and operculum, structures at the intersection of the temporal and frontal lobes (Figure 5.12). Primary gustatory cortex is connected to secondary processing areas of the orbitofrontal cortex, providing an anatomical basis for the integration of tastes and smells. While there are only five types of taste cells, we are capable of experiencing a complex range of tastes. This ability must result from the integration of information conveyed from the taste cells and processed in areas like the orbitofrontal cortex. The tongue does more than just taste. Some papillae contain nociceptive receptors, a type of pain receptor. These are activated by irritants such as capsaicin (contained in chili peppers), carbon dioxide (carbonated drinks), and acetic acid (vinegar). The output from these receptors follows a different path, forming the trigeminal nerve (cranial nerve V). This nerve not only carries pain information but also signals position and temperature information. You are well aware of the reflex response to activation by these irritants if you have ever eaten a hot chili: salivation, tearing, vasodilation (the red face), nasal secretion, bronchospasm (coughing), and decreased respiration. All these are meant to dilute that irritant and get it out of your system as quickly as possible.

Gustation | 177 b

Circumvallate papillae Papilla Taste bud

Taste cells Foliate papillae Basal cells

Gustatory afferent axons

Salty Sweet

Fungiform papillae

Sour

Taste strength a

Chorda tympani nerve

Bitter

Taste pore c

Circumvallate papillae

Foliate papillae

Fungiform papillae

Thalamus Taste zone of cortex

Nucleus of the solitary tract

Glossopharyngeal cranial nerve

Taste receptor cells

Facial cranial nerve Vagus cranial nerve

d

FIGURE 5.12 The gustatory transduction pathway. (a) Three different types of taste papillae span the surface of the tongue. Each cell is sensitive to one of five basic tastes: salty, sweet, sour, bitter, and umami. The bar graph shows how sensitivity for four taste sensations varies between the three papillae. (b) The papillae contain the taste buds. (c) Taste pores on the surface of the tongue open into the taste bud, which contains taste cells. (d) The chorda tympani nerve, formed by the axons from the taste cells, joins with the facial nerve to synapse in the nucleus of the solitary tract in the brain stem, as do the sensory nerves from the GI tract via the vagus nerve. The taste pathway projects to the ventral posterior medial nucleus of the thalamus and information is then relayed to the gustatory cortex in the insula.

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Gustatory Processing Taste perception varies from person to person because the number and types of papillae and taste buds vary considerably between individuals. In humans, the number of taste buds varies from 120 to 668 per cm2. Interestingly, women generally have more taste buds than men (Bartoshuk et al., 1994). People with large numbers of taste buds are known as supertasters. They taste things more intensely, especially bitterness, and feel more pain from tongue irritants. You can spot the two ends of the

tasting spectrum at the table. One is pouring on the salsa or drinking grapefruit juice while the other is cringing. The basic tastes give the brain information about the types of food that have been consumed. The sensation of umami tells the body that protein-rich food is being ingested, sweet tastes indicate carbohydrate intake, and salty tastes give us information that is important for the balance between minerals or electrolytes and water. The tastes of bitter and sour likely developed as warning signals. Many toxic plants taste bitter, and a strong bitter taste can induce vomiting. Other evidence suggesting that bitterness is a warning signal

DELICIOUS 10

10

I really want another piece

Motivation

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Pleasantness PLEASANT

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Another piece would be nice

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–8 –10 1

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Eating more would make me sick

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b FIGURE 5.13 The neural correlates of satiation. (a) Participants use a 10-point scale to rate the motivation and pleasantness of chocolate when offered a morsel seven times during the PET session. Desire and enjoyment declined over time. (b) Activation as measured during PET scanning during repeated presentations of chocolate (red). Water was presented during the first and last scans (blue). Across presentations, activity dropped in primary gustatory cortex (left) and increased in orbitofrontal cortex (right). The former could indicate an attenuated response to the chocolate sensation as the person habituates to the taste. The latter might correspond to a change in the participants’ desire (or aversion) to chocolate.

Somatosensation | 179 is the fact that we can detect bitter substances 1,000 times better than, say, salty substances. Therefore, a significantly smaller amount of bitter tastant will yield a taste response, allowing toxic bitter substances to be avoided quickly. No wonder supertasters are especially sensitive to bitter tastes. Similarly, but to a lesser extent, sour indicates spoiled food (e.g., “sour milk”) or unripe fruits. Humans can readily learn to discriminate similar tastes. Richard Frackowiak and his colleagues at University College London (Castriota-Scanderberg et al., 2005) studied wine connoisseurs (sommeliers), asking how their brain response compared to that of nonexperts when tasting wines that varied in quite subtle ways. In primary gustatory areas, the two groups showed a very similar response. The sommeliers, however, exhibited increased activation in the insula cortex and parts of the orbitofrontal cortex in the left hemisphere, as well as greater activity bilaterally in dorsolateral prefrontal cortex. This region is thought to be important for high-level cognitive processes such as decision making and response selection (see Chapter 12). The orbitofrontal cortex also appears to play an important role in processing the pleasantness and reward value of eating food. Dana Small and her colleagues (2001) at Northwestern University used positron emission tomography (PET) to scan the brains of people as they ate chocolate (Figure 5.13). During testing, the participants rated the pleasantness of the chocolate and their desire to eat more chocolate. Initially, the chocolate was rated as very pleasant and the participants expressed a desire to eat more. But as the participants became satiated, their desire for more chocolate dropped. Moreover, although the chocolate was still perceived as pleasant, the intensity of their pleasure ratings decreased. By comparing the neural activation in the beginning trials with the trials at the end of the study, the researchers were able to determine which areas of the brain participated in processing the reward value of the chocolate (the pleasantness) and the motivation to eat (the desire to have more chocolate). The posteromedial portion of the orbitofrontal cortex was activated when the chocolate was highly rewarding and the motivation to eat more was strong. In contrast, the posterolateral portion of the orbitofrontal cortex was activated during the satiated state, when the chocolate was unrewarding and the motivation to eat more was low. Thus, the orbitofrontal cortex appears to be a highly specialized taste-processing region containing distinct areas able to process opposite ends of the reward value spectrum associated with eating.

TAKE-HOME MESSAGES ■

Gustation and olfaction are known together as the chemical senses because the initial response is to molecules (chemicals) in the environment.

The five basic tastes are salty, sour, bitter, sweet, and umami. The perception of more complex tastes arises from the complex cortical processing of these individual tastes in areas of the brain such as the secondary gustatory cortex in the orbitofrontal region. Signal transduction is initiated when a taste cell in the mouth responds to a tastant by depolarizing and sends a signal to the gustatory nucleus in the dorsal medulla. From there, a signal zips to the ventral posterior medial (VPM) nucleus of the thalamus. The VPM synapses with the primary gustatory cortex found in the operculum and insula. The primary gustatory cortex connects with the secondary processing areas found in the orbitofrontal cortex. The orbitofrontal cortex is also involved in processing the reward value of food and the resulting motivation to eatfood.

Somatosensation Somatosensory perception is the perception of all mechanical stimuli that affect the body. This includes interpretation of signals that indicate the position of our limbs and the position of our head, as well as our sense of temperature, pressure, and pain. Perhaps to a greater degree than with our other sensory systems, the somatosensory system includes an intricate array of specialized receptors and vast projections to many regions of the central nervous system.

Neural Pathways of Somatosensation Somatosensory receptors lie under the skin (Figure 5.14) and at the musculoskeletal junctions. Touch is signaled by specialized receptors in the skin, including Meissner’s corpuscles, Merkel’s cells, Pacinian corpuscles, and Ruffini corpuscles. These receptors differ in how quickly they adapt and in their sensitivity to various types of touch, such as deep pressure or vibration. Pain is signaled by nociceptors, the least differentiated of the skin’s sensory receptors. Nociceptors come in three flavors: thermal receptors that respond to heat or cold, mechanical receptors that respond to heavy mechanical stimulation, and polymodal receptors that respond to a wide range of noxious stimuli including heat, mechanical insults, and chemicals. The experience of pain is often the result of chemicals, such as histamine, that the body releases in response to injury. Nociceptors are located on the skin, below the skin, and in muscles and joints. Afferent pain neurons may be either myelinated or unmyelinated. The myelinated fibers quickly conduct information about pain. Activation of these cells usually produces immediate action. For example, when you touch a hot stove, the myelinated nociceptors can trigger a response that will cause you to quickly

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Skin cells

Free nerve endings Meissner's corpuscle

Merkel's cell

Epidermis Pacinian corpuscle Ruffini corpuscle

Dermis

The somatosensory receptors enter the spinal cord via the dorsal root (Figure 5.15). Some synapse on motor neurons in the spinal cord to form reflex arcs. Other axons synapse on neurons that send axons up the dorsal column of the spinal cord to the medulla. From here, information crosses over to the ventral posterior nucleus of the thalamus and then on to the cerebral cortex. As in vision (which is covered later in the chapter) and audition, the primary peripheral projections to the brain are crosswired; that is, information from one side of the body is represented primarily in the opposite, or contralateral, hemisphere. In addition to the cortical projections, proprioceptive and somatosensory information is projected to many subcortical structures, such as the cerebellum.

Somatosensory Processing

FIGURE 5.14 Somatosensory receptors underneath the skin. Merkel’s cells detect regular touch; Meissner’s corpuscles, light touch; Pacinian corpuscles, deep pressure; Ruffini corpuscles, temperature. Nociceptors (also known as free nerve endings), detect pain.

lift your hand, possibly even before you are aware of the temperature. The unmyelinated fibers are responsible for the duller, longer-lasting pain that follows the initial burn and reminds you to care for the damaged skin. Specialized nerve cells provide information about the body’s position, or what is called proprioception (proprius: Latin for “own,” –ception: “receptor”; thus, a receptor for the self). Proprioception allows the sensory and motor systems to represent information about the state of the muscles and limbs. Proprioceptive cues, for example, signal when a muscle is stretched and can be used to monitor if that movement is due to an external force or from our own actions (see Chapter 8). Somatosensory receptors have their cell bodies in the dorsal-root ganglia (or equivalent cranial nerve ganglia).

The initial cortical receiving area is called primary somatosensory cortex or S1 (Figure 5.16a), which includes Brodmann areas 1, 2, and 3. S1 contains a somatotopic representation of the body, called the sensory homunculus (Figure 5.16b). Recall from Chapter 2 that the relative amount of cortical representation in the sensory homunculus corresponds to the relative importance of somatosensory information for that part of the body. For example, the hands cover a much larger portion of the cortex than the trunk does. The larger representation of the hands is essential given the great precision we need in using our fingers to manipulate objects and explore surfaces. When blindfolded, we can readily identify an object placed in our hand, but we would have great difficulty in identifying an object rolled across our back. Somatotopic maps show considerable variation across species. In each species, the body parts that are the most important for sensing the outside world through touch are the ones that have the largest cortical representation. A great deal of the spider monkey’s cortex is devoted to its tail, which it uses to explore objects that might be edible foods or for grabbing onto tree limbs. The rat, on the other hand, uses its whiskers to explore the world; so a vast portion of the rat somatosensory cortex is devoted to representing information obtained from the whiskers (Figure 5.17). Secondary somatosensory cortex (S2) builds more complex representations. From touch, for example, S2 neurons may code information about object texture and size. Interestingly, because of projections across the corpus callosum, S2 in each hemisphere receives information from both the left and the right sides of the body. Thus, when we manipulate an object with both hands, an integrated representation of the somatosensory information can be built up in S2.

Somatosensation | 181 Primary somatosensory cortex To thalamus

Midbrain Thalamus

4 Output from the medulla crosses to innervate the contralateral thalamus, and from there projects to the somatosensory cortex. Medulla 3 The first synapse of the ascending column is made in the medulla.

Spinal cord 2 The axons of the receptors enter the dorsal horn of the spinal cord and synapse on spinal neurons, some of which ascend along the dorsal column.

Touch receptors 1 Touch receptors detect stimulation of the skin and generate action potentials

FIGURE 5.15 The major somatosensory pathway (representative). From skin to cortex, the primary pathway of the somatosensory system.

Plasticity in the Somatosensory Cortex Looking at the somatotopic maps may make you wonder just how much of that map is set in stone. What if you worked at the post office for many years sorting mail. Would you see changes in parts of the visual cortex that discriminate numbers? Or if you were a professional violinist, would your motor cortex be any bigger than that of the person who has never picked up a bow? Would anything happen to the part of your brain that represents your finger if you lost it in an accident? Would that part atrophy, or does the neighboring finger expand its representation and become more sensitive? In 1949, Donald Hebb bucked the assumption that the brain was set in stone after the early formative years. He suggested a theoretical framework for how

functional reorganization, or what neuroscientists refer to as cortical plasticity, might occur in the brain through the remodeling of neuronal connections. Since then, more people have been looking for and observing brain plasticity in action. Michael Merzenich (Merzenich & Jenkins, 1995; Merzenich et al., 1988) at the University of California, San Francisco, and Jon Kaas (1995) at Vanderbilt University discovered that in adult monkeys, the size and shape of the cortical sensory and motor maps can be altered by experience. For example, when the nerve fibers from a finger to the spinal cord are severed (deafferented), the relevant part of the cortex no longer responds to the touch of that finger (Figure 5.18). Although this is no big surprise, the strange part is that the area of the cortex that formerly represented the denervated finger soon becomes active again. It begins to

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Central sulcus

Spider monkey

Precentral gyrus

Rat

Postcentral gyrus

S1 S2

Critical somatosensory representation

a Hand area

Arm and trunk area

FIGURE 5.17 Variation in the organization of somatosensory cortex reflects behavioral differences across species. The cortical area representing the tail of the spider monkey is large because this animal uses its tail to explore the environment as well as for support. The rat explores the world with its whiskers; clusters of neurons form whisker barrels in the rat somatosensory cortex.

Face area

Normal cortical map 4

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e Kn

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Digits 3 and 4 sewn together 1

Somatosensory Cortex

FIGURE 5.16 (a) Somatosensory cortex (S1) lies in the postcentral gyrus, the most anterior portion of the parietal lobe. The secondary somatosensory cortex (S2) is ventral to S1. (b) The somatosensory homunculus as seen along the lateral surface and in greater detail in the coronal section. Note that the body parts with the larger cortical representations are most sensitive to touch.

D5

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FIGURE 5.18 Reorganization of sensory maps in the primate cortex. (a) In a mapping of the somatosensory hand area in normal monkey cortex, the individual digit representations can be revealed by single-unit recording. (b) If two fingers of one hand are sewn together, months later the cortical maps change such that the sharp border once present between the sewn fingers is now blurred.

Somatosensation | 183 respond to stimulation from the finger adjacent to the amputated finger. The surrounding cortical area fills in and takes over the silent area. Similar changes are found when a particular finger is given extended sensory stimulation: It gains a little more acreage on the cortical map. This functional plasticity suggests that the adult cortex is a dynamic place where changes can still happen, and it demonstrates a remarkable plasticity. Extending these findings to humans, Vilayanur Ramachandran at the University of California, San Diego, studied the cortical mapping of human amputees. Look again at the human cortical somatosensory map in Figure 5.16b. What body part is represented next to the fingers and hand? Ramachandran reasoned that a cortical rearrangement ought to take place if an arm is amputated, just as had been found for the amputation of a digit in monkeys. Such a rearrangement might be expected to create bizarre patterns of perception, since the face area is next to the hand and arm area. Indeed, in one case study, Ramachandran examined a young man whose arm had been amputated just above the elbow a month earlier (1993). When a cotton swab was brushed lightly against his face, he reported feeling his amputated hand being touched! Feelings of sensation in missing limbs are the well-known phenomenon of phantom limb sensation. The sensation in the missing limb is produced by touching a body part that has appropriated the missing limb’s old acreage in the cortex. In this case, the

sensation was introduced by stimulating the face. Indeed, with careful examination, a map of the young man’s hand could be demonstrated on his face (Figure 5.19). These examples of plasticity led researchers to wonder if changes in experience within the normal range—say, due to training and practice—also result in changes in the organization of the adult human brain. Thomas Elbert and his colleagues at the University of Konstanz used magnetoencephalography (MEG) to investigate the somatosensory representations of the hand area in violin players (Elbert et al., 1995). They found that the responses in the musicians’ right hemisphere, which controls the left-hand fingers that manipulate the violin strings, were stronger than those observed in nonmusicians (Figure 5.20). What’s more, they observed that the size of the effect (the enhancement in the response) correlated with the age at which the players began their musical training. These findings suggest that a larger cortical area was dedicated to representing the sensations from the fingers of the musicians, owing to their altered but otherwise normal sensory experience. Another study used a complex visual motor task: juggling. After 3 months of training, the

D1

String players Controls

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Cortical response is larger for musicians who begin training before age 12.

30 25 Cortical response

B T

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FIGURE 5.19 Perceived sensation of a phantom, amputated hand following stimulation of the face. A Q-tip was used to lightly brush different parts of the face. The letters indicate the patient’s perceptual experience. The region labeled T indicates the patient experienced touch on his phantom thumb. P is from the pinkie, I, the index finger, and B the ball of the thumb.

5 10 15 20 25 Age at inception of musical practice

FIGURE 5.20 Increase in cortical representation of the fingers in musicians who play string instruments. (a) Source of MEG activity for controls (yellow) and musicians (red) following stimulation of the thumb (D1) and fifth finger (D5). Thelength of the arrows indicates the extent of the responsive region. (b) The size of the cortical response, plotted as a function of the age at which the musicians begin training. Responses were larger for those who began training before the age of 12 years; controls are shown at the lower right of the graph.

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new jugglers had increased gray matter in the extrastriate motion-specific area in their visual cortex and in the left parietal sulcus, an area that is important in spatial judgments. (Draganski et al., 2004). Indeed, there is evidence that cortical reorganization can occur after just 15 to 30 minutes of practice (Classen et al., 1998). The kicker is, however, that when the jugglers stopped practicing, these areas of their brain returned to their pretraining size, demonstrating something that we all know from experience: Use it or lose it. The realization that plasticity is alive and well in the brain has fueled hopes that stroke victims who have damaged cortex with resultant loss of limb function may be able to structurally reorganize their cortex and regain function. How this process might be encouraged is actively being pursued. One approach is to better understand the mechanisms involved.

Mechanisms of Cortical Plasticity Most of the evidence for the mechanisms of cortical plasticity comes from animal studies. The results suggest a cascade of effects, operating across different timescales. Rapid changes probably reflect the unveiling of weak connections that already exist in the cortex. Longer-term plasticity may result from the growth of new synapses and/or axons. Immediate effects are likely to be due to a sudden reduction in inhibition that normally suppresses inputs from neighboring regions. Reorganization in the motor cortex has been found to depend on the level of gamma-aminobutyric acid (GABA), the principal inhibitory neurotransmitter (Ziemann et al., 2001). When GABA levels are high, activity in individual cortical neurons is relatively stable. If GABA levels are lower, however, then the neurons may respond to a wider range of stimuli. For example, a neuron that responds to the touch of one finger will respond to the touch of other fingers if GABA is blocked. Interestingly, temporary deafferentation of the hand (by blocking blood flow to the hand) leads to a lowering of GABA levels in the brain. These data suggest that short-term plasticity may be controlled by a release of tonic inhibition on synaptic input (thalamic or intracortical) from remote sources. Changes in cortical mapping over a period of days probably involve changes in the efficacy of existing circuitry. After loss of normal sensory input (e.g., through amputation or peripheral nerve section), cortical neurons that previously responded to that input might undergo “denervation hypersensitivity.” That is, the strength of the responses to any remaining weak excitatory input is upregulated: Remapping might well depend on such modulations of synaptic efficacy. Strengthening of synapses is enhanced in the motor cortex by the neurotransmitters

norepinephrine, dopamine, and acetylcholine; it is decreased in the presence of drugs that block the receptors for these transmitters (Meintzschel & Ziemann, 2005). These changes are similar to the forms of long-term potentiation and depression in the hippocampus that are thought to underlie the formation of spatial and episodic memories that we will discuss in Chapter 9. Finally, some evidence in animals suggests that the growth of intracortical axonal connections and even sprouting of new axons might contribute to very slow changes in cortical plasticity.

TAKE-HOME MESSAGES ■

Corpuscles located in the skin respond to somatosensory touch information. Nociceptors (free nerve endings) respond to pain and temperature information. Nerve cells at the junctions of muscles and tendons provide proprioceptive information. Primary somatosensory cortex (S1) contains a homunculus of the body, wherein the more sensitive regions encompass relatively larger areas of cortex. Somatosensory representations exhibit plasticity, showing variation in extent and organization as a function of individual experience.

Vision Now let’s turn to a more detailed analysis of the most widely studied sense: vision. Like most other diurnal creatures, humans depend on the sense of vision. Although other senses, such as hearing and touch, are also important, visual information dominates our perceptions and appears even to frame the way we think. Much of our language, even when used to describe abstract concepts with metaphors, makes reference to vision. For example, we say “I see” to indicate that something is understood, or “Your hypothesis is murky” to indicate confused thoughts.

Neural Pathways of Vision One reason vision is so important is that it enables us to perceive information at a distance, to engage in what is called remote sensing or exteroceptive perception. We need not be in immediate contact with a stimulus to process it. Contrast this ability with the sense of touch. For touch, we must be in direct contact with the stimulus. The advantages of remote sensing are obvious. An organism surely can avoid a predator better when it can detect the predator at a distance. It is probably too late to flee once a shark has sunk its teeth into you, no matter how fast your neural response is to the pain.

Vision | 185

The Receptors Visual information is contained in the light reflected from objects. To perceive objects, we need sensory detectors that respond to the reflected light. As light passes through the lens of the eye, the image is inverted and focused to project on the back surface of the eye (Figure 5.21), the retina. The retina is only about 0.5 mm thick, but it is made up of 10 densely packed layers of neurons. The deepest layers are composed of millions of photoreceptors, the rods and cones. These contain photopigments, protein molecules that are sensitive to light. When exposed to light, the photopigments become unstable and split apart. Unlike most neurons, rods and cones do not fire action potentials. The decomposition of the photopigments alters the membrane potential of the photoreceptors and triggers action potentials in downstream neurons. Thus, photoreceptors provide for translation of the external stimulus of light into an internal neural signal that the brain can interpret.

The rods contain the pigment rhodopsin, which is destabilized by low levels of light. Rods are most useful at night when light energy is reduced. Rods also respond to bright light, but the pigment quickly becomes depleted and the rods cease to function until it is replenished. Because this takes several minutes, they are of little use during the day. Cones contain a different type of photopigment, called a photopsin. Cones require more intense levels of light but can replenish their photopigments rapidly. Thus, cones are most active during daytime vision. There are three types of cones, defined by their sensitivity to different regions of the visible spectrum: (a) a cone that responds to short wavelengths, the blue part of the spectrum; (b) one that responds to medium wavelengths, the greenish region; and (c) one that responds to the long “reddish” wavelengths (Figure 5.22). The activity of these three different receptors ultimately leads to our ability to see color.

Light

Optic nerve fibers

Ganglion cells

Cornea Iris Lens

Middle layer Fovea Retina

Optic nerve Receptor cells

Rod Cone Near fovea: cones predominate

Toward periphery: % of rods increase

FIGURE 5.21 Anatomy of the eye and retina. Light enters through the cornea and activates the receptor cells of the retina located along the rear surface. There are two types of receptor cells: rods and cones. The output of the receptor cells is processed in the middle layer of the retina and then relayed to the central nervous system via the optic nerve, the axons of the ganglion cells.

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Relative response

430

“Blue” cones

530 560

Rods

“Red” cones “Green” cones

400

450

500 550 Wavelength (nm)

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FIGURE 5.22 Spectral sensitivity functions for rods and the three types of cones. The short-wavelength (“blue”) cones are maximally responsive tolight with a wavelength of 430 nm. The peak sensitivities of the medium-wavelength (“green”) and long-wavelength (“red”) cones are shifted to longer wavelengths. White light, such as daylight, activates all three receptors because it contains all wavelengths.

Rods and cones are not distributed equally across the retina. Cones are densely packed near the center of the retina, in a region called the fovea. Few cones are in the more peripheral regions of the retina. d In contrast, rods are distributed l fiel sua i v t throughout the retina. You can Lef easily demonstrate the differential distribution of rods and cones by having a friend slowly bring a colored marker into your view from one side of your head. Notice that you see the marker and its shape well before you Temporal identify its color, because of the sparse distribution of cones in the retina’s peripheral regions.

The Retina to the Central Nervous System The rods and cones are connected to bipolar neurons that then synapse with the ganglion cells, the output layer of the retina. The axons of these cells form a bundle, the optic nerve, that transmits information to the central nervous system. Before any information is shipped down the optic nerve, however, extensive processing occurs within the retina, an elaborate convergence of information. Indeed, though humans have an estimated 260 million

photoreceptors, we have only 2 million ganglion cells to telegraph information from the retina. Many rods feed into a single ganglion cell. By summing their outputs, the rods can activate a ganglion cell even in low light situations. For cones, however, the story is different: Each ganglion cell is innervated by only a few cones. Thus, they carry much more specific information from only a few receptors, ultimately providing a sharper image. The compression of information, as with the auditory system, suggests that higher-level visual centers should be efficient processors to unravel this information and recover the details of the visual world. Figure 5.23 diagrams how visual information is conveyed from the eyes to the central nervous system. As we discussed in the last chapter, before entering the brain, each optic nerve splits into two parts. The temporal (lateral) branch continues to traverse along the ipsilateral side. The nasal (medial) branch crosses over to project to the contralateral side; this crossover place is called the optic chiasm. Given the eye’s optics, the crossover of nasal fibers ensures that visual information from each side of external space will be projected to contralateral brain structures. Because of

Right visual field

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Optic radiation Primary visual cortex FIGURE 5.23 The primary projection pathways of the visual system. The optic fibers from the temporal half of the retina project ipsilaterally, and the nasal fibers cross over at the optic chiasm. In this way, the input from each visual field is projected to the primary visual cortexin the contralateral hemisphere after the fibers synapse in the lateral geniculate nucleus (geniculocortical pathway). A small percentage of visual fibers of the optic nerve terminate in the superior colliculus and pulvinar nucleus.

Vision | 187 the retina’s curvature, the temporal half of the right retina is stimulated by objects in the left visual field. In the same fashion, the nasal hemiretina of the left eye is stimulated by this same region of external space. Because fibers from each nasal hemiretina cross, all information from the left visual field is projected to the right hemisphere, and information from the right visual field is projected to the left hemisphere. Each optic nerve divides into several pathways that differ with respect to where they terminate in the subcortex. Figure 5.23 focuses on the pathway that contains more than 90 % of the axons in the optic nerve, the retinogeniculate pathway, the projection from the retina to the lateral geniculate nucleus (LGN) of the thalamus. The LGN is made up of six layers. One type of ganglion cell, the M cell, sends output to the bottom two layers. Another type of ganglion cell the P cell, projects to the top four layers. The remaining 10 % of the optic nerve fibers innervate other subcortical structures, including the pulvinar nucleus of the thalamus and the superior colliculus of the midbrain. Even though these other receiving nuclei are innervated by only 10 % of the fibers, these pathways are still important. The human optic nerve is so large that 10 % of it constitutes more fibers than are found in the entire auditory pathway. The superior colliculus and pulvinar nucleus play a large role in visual attention. The final projection to the visual cortex is via the geniculocortical pathway. This bundle of axons exits the LGN and ascends to the cortex, and almost all of the fibers terminate in the primary visual cortex (V1) of the occipital lobe. Thus visual information reaching the cortex has been processed by at least four distinct neurons: photoreceptors, bipolar cells, ganglion cells, and LGN cells. Visual information continues to be processed as it passes through higher order visual areas in the cortex. There are diseases and accidents that damage the eyes’ photoreceptors, but otherwise leave the visual pathway intact. Until recently, people in this situation would go blind. But things are looking brighter for these patients thanks to microelectronics (see “How the Brain Works: When the Receptors No Longer Function”).

TAKE-HOME MESSAGES ■

Light activates the photoreceptors, the rods and cones, on the retina. The optic nerve is formed from the axons of the ganglion cells, some of which decussate at the optic chiasm. Axons in the optic nerve synapse on the LGN, and from the LGN become the optic radiations that are sent to V1. Ten percent of the fibers from the retina innervate nonLGN subcortical structures, including the pulvinar and superior colliculus.

Keeping the Picture Straight: Retinotopic Maps Due to the optics of the eye, light reflecting off of objects in the environment strikes the eye in an orderly manner. Light reflected off of an object located to the right of someone’s gaze will activate photoreceptors on the medial, or nasal, side of the right retina and lateral or temporal side of the left retina. As this information is projected upstream via the optic nerve, however, the direct link between neural activity and space is lost. Nonetheless, neurons in the visual system represent space. This is shown by the fact that most visual neurons only respond when a stimulus is presented in a specific region of space, or what is defined as the receptive field of the neuron. For example, a cell in the right visual cortex may respond to a bar of light, but only if that bar is presented in a specific region of space (e.g., the upper left visual field; see Figure 3.19). Moreover, there is an orderly relationship between the receptive fields of neighboring cells. Thus, external space is represented continuously within neural regions such as the LGN or V1. As with the somatosensory and auditory systems, the receptive fields of visual cells form an orderly mapping between an external dimension (in this case, spatial location) and the neural representation of that dimension. In vision, these topographic representations are referred to as retinotopic maps. A full retinotopic map contains a representation of the entire contralateral hemifield (e.g., left hemisphere V1 will have a full representation of the right side of space). Receptive fields range in size, becoming larger across the visual system (Figure 5.24). LGN cells have receptive fields responding only if the stimulus falls within a very limited region of space, about one degree of visual angle. Cells in V1 have slightly larger receptive fields, and this magnification process continues through the visual system: Cells in the temporal lobe have receptive fields that may encompass an entire hemifield.

TAKE-HOME MESSAGES ■

Visual neurons respond only to a stimulus that is presented in a specific region of space. This property is known as the receptive field of the cell. Visual cells form an orderly mapping between spatial location and the neural representation of that dimension. In vision, these topographic representations are referred to as retinotopic maps.

Cortical Visual Areas A primary physiological method for establishing visual areas is to measure how spatial information is represented across a region of cortex. Figure 5.24 shows a map of the

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When the Receptors No Longer Function: The Retinal Implant After being blind for 5 years, a patient sits at a table and is able to identify not only where a mug and various cutlery are placed, but can also tell that his name, spelled out in large letters, has been spelled incorrectly. He is one of three patients who have had an electronic chip implanted behind the retina (Zrenner et al., 2011). This chip is designed for patients who are suffering from blindness caused by degenerative diseases that affect photoreceptors and result in progressive vision loss. In the first few years of blindness the other cells of the retina remain intact—a situation this particular retinal implant uses to its advantage. The tiny implant chip, measuring 3 mm by 3.1 mm, contains 1,500 light-sensitive microphotodiodes (Figure1). Light enters the eye through the lens, passes through the transparent retina, and hits the chip. The image is simultaneously captured several times per minute by all of the photodiodes, each of which controls a tiny amplifier connected to an electrode, together known as an element (pixel). Each element generates a voltage at its

electrode, the strength of which depends on the intensity of light hitting the photodiode. The voltage then passes to the adjacent bipolar neurons in the retina, and the signal proceeds through the rest of the visual pathway. One question facing those designing retinal implants is, how many photodiodes are needed to gain an acceptable image? When you consider that the eye contains millions of photoreceptors, 1,500 seems like a drop in the bucket. Indeed, this number produces only crude images. This system is in its infancy, but it allows a blind person to navigate and make simple discriminations. Thechip is powered by an implanted cable that runs fromthe eye under the temporalis muscle and out from behind the ear, where it is attached to a wirelessly operated power control unit that the patient wears around his neck. This implant was placed temporarily, for just a few weeks, to test the concept. The next-generation system, currently being tested, is not cable bound. Instead, an encapsulated coil is implanted behind the ear and connected to a transmitter that magnetically attaches to an outside power coil.

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Vision | 189 visual areas of the cortex as defined by their physiology. Each box in the figure stands for a distinct region of visual processing, defined because the region contains its own retinotopic map. Thus, the boundaries between anatomically adjacent visual areas are marked by topographic discontinuities (Figure 5.25). As one area projects to another, topography and precise spatial information is preserved by these multiple retinotopic maps, at least in early visual areas. Over 30 distinct cortical visual areas have been identified in the monkey, and the evidence indicates that humans have even more. Note that the names for the areas shown in Figure 5.24 primarily draw on the nomenclature developed by physiologists (see Chapter 2). Striate cortex, or V1, is the initial projection region of geniculate axons. Although other areas have names such as V2, V3, and V4, this numbering scheme should not be taken to mean that the synapses proceed sequentially from one area to the next. The lines connecting these extrastriate visual areas demonstrate extensive convergence and divergence across visual areas. In addition, connections between many areas are reciprocal; areas frequently receive input from an area to which they project.

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FIGURE 5.24 Prominent cortical visual areas and the pattern of connectivity in the macaque brain. Whereas all cortical processing begins in V1, the projections form two major processing streams, one along a dorsal pathway and the other along a ventral pathway (see Chapter 6). The stimulus required to produce optimal activation of a cell becomes more complex along the ventral stream. In addition, the size of the receptive fields increases, ranging from the 0.5° span of a V1 cell to the 40° span of a cell in area TE. Thelabels for the areas reflect a combination of physiological (e.g., V1) and anatomical (e.g., LIP) terms.

Cellular Properties Vary Across Cortical Visual Areas Why would it be useful for the primate brain to have evolved so many visual areas? One possibility is that visual processing is hierarchical. Each area, representing the stimulus in a unique way, successively elaborates on the representation derived by processing in earlier areas. The simple cells of the primary visual cortex calculate edges. Complex cells in secondary visual areas use the information from many simple cells to represent corners and edge terminations. In turn, higher order visual neurons integrate information from complex cells to

represent shapes. Successive elaboration culminates in formatting the representation of the stimulus so that it matches (or doesn’t match) information in memory. An interesting idea, but there is a problem. As Figure 5.24 shows, there is no simple hierarchy; rather, extensive patterns of convergence and divergence result in multiple pathways. An alternative hypothesis is based on the idea that visual perception is an analytic process. Although each visual area provides a map of external space, the maps represent different types of information. For instance, neurons in some

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FIGURE 5.25 The boundaries between adjacent visual areas have topographic discontinuities. An area is defined by a discontinuity or reversal in the retinotopic representation. Along the continuous ribbon of cortex shown here, seven different visual areas can be identified. However, processing is not restricted to proceeding from one area to the next in a sequential order. For example, axons from V2project to V3, V4, and V5/MT.

areas are highly sensitive to color variation. In other areas, they are sensitive to movement but not to color. Based on this hypothesis, neurons within an area not only code where an object is located in visual space but also provide information about the object’s attributes. By this perspective, visual perception can be considered to entail a divide-and-conquer strategy. Rather than all attributes of an object being represented by all visual areas, each visual area provides its own limited analysis. Processing is distributed and specialized. As signals advance through the visual system, different areas elaborate on the initial information in V1 and begin to integrate this information across dimensions to form recognizable percepts. Early work on these ideas is presented in “Milestones in Cognitive Neuroscience: Pioneers in the Visual Cortex.”

Specialized Function of Visual Areas in Monkeys Extensive physiological evidence supports the specialization hypothesis. Consider cells in area MT (sometimes

referred to as V5), so named because it lies in the middle temporal lobe region of the macaque monkey, a species used in many physiology studies. Single-cell recordings reveal that neurons in this region do not show specificity regarding the color of the stimulus. These cells will respond similarly to either a green or a red circle on a white background. Even more striking, these neurons respond weakly when presented with an alternating pattern of red and green stripes whose colors are equally bright. In contrast, MT neurons are quite sensitive to movement and direction, as Figure 5.26 shows (Maunsell & Van Essen, 1983). The stimulus, a rectangular bar, was passed through the receptive field of a specific MT cell in varying directions. The cell’s response was greatest when the stimulus was moved downward and left. In contrast, this cell was essentially silent when the stimulus was moved upward or to the right. Thus the cell’s activity correlates with two attributes of the stimulus. First, the cell is active only when the stimulus falls within its receptive field. Second, the response is greatest when the stimulus moves in a certain direction. Activity in MT cells also correlates with the speed of motion. The cell in Figure 5.26 responded maximally when the bar was moved rapidly. At lower speeds, the bar’s movement in the same direction failed to raise the response rate above baseline.

Specialized Function of Human Visual Areas Single-cell recording studies have provided physiologists with a powerful tool for mapping the visual areas in the monkey brain and characterizing the functional properties of the neurons within these areas. This work has yielded strong evidence that different visual areas are specialized to represent distinct attributes of the visual scene. Inspired by these results, researchers have employed neuroimaging techniques to describe the functional architecture of the human brain. In a pioneering study, Semir Zeki (1993) of University College London and his colleagues at London’s Hammersmith Hospital used positron emission tomography (PET) to explore similar principles in the human visual system, starting with the goal of identifying areas that were involved in processing color or motion information. They used subtractive logic by factoring out the activation in a control condition from the activation in an experimental condition. Let’s check out the color experiment to see how this works. For the control condition, participants passively viewed a collage of achromatic rectangles. Various shades of gray, spanning a wide range of luminances, were chosen. The control stimulus was expected to activate neural regions with cells that are contrast sensitive (e.g., sensitive to differences in luminance). For the experimental condition, the gray patches were replaced by a variety of colors (Figure 5.27a). Each

Vision | 191

MILESTONES IN COGNITIVE NEUROSCIENCE

Pioneers in the Visual Cortex Like the voyages of 15th-century European explorers, initial investigations into the neurophysiology of the cerebral cortex required a willingness to sail in uncharted waters. The two admirals in this enterprise were David Hubel and Torsten Wiesel. Hubel and Wiesel arrived at Johns Hopkins University in the late 1950s, hoping to extend the pioneering work of Steve Kuffler (1953). Kuffler’s research had elegantly described the receptive-field organization of ganglion cells in the cat retina, laying out the mechanisms that allowed cells to detect the edges that define objects in the visual world. Rather than focusing on the lateral geniculate nucleus (LGN), the next relay in the system, Hubel and Wiesel (1977) set their sights on the primary visual cortex. Vernon Mountcastle, another Hopkins researcher, was just completing his seminal work, in which he laid out the complex topographic organization of the somatosensory cortex (Mountcastle, 1976). Hubel and Wiesel were inspired to look for similar principles in vision. During the first few weeks of their recordings, Hubel and Wiesel were puzzled by what they observed. Although they had little difficulty identifying individual

cortical cells, the cells failed to respond to the kinds of stimuli that had proved so effective in Kuffler’s studies: small spots of light positioned within a cell’s receptive fields. Indeed, the lack of consistent responses made it difficult to determine where the receptive field was situated. Hubel and Wiesel had a breakthrough, though, when they switched to dark spots, which they created by placing an opaque disk on a glass slide. Although the cell did not respond to the dark spot, Hubel and Wiesel noticed a burst in activity as the edge of the glass moved across part of the retina. After hours of play with this stimulus, the first organizational principle of primary visual cortex neurons became clear: Unlike the circular receptive fields of ganglion cells, cortical neurons were responsive to edges. Subsequent work revealed that LGN cells and ganglion cells behave similarly: Both are maximally excited by small spots of light. Such cells are best characterized as exhibiting a concentric center–surround organization. Figure 1 shows the receptive field of an LGN cell. Whena spot of

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FIGURE 1 Characteristic response of a lateral geniculate nucleus (LGN) cell. Cells in the LGN have concentric receptive fields with either an on-center, off-surround organization or an off-center, on-surround organization. The on-center, off-surround cell shown here fires rapidly when the light encompasses the center region (a) and is inhibited when the light is positioned over the surround (b). Astimulus that spans both the center and the surround produces little change in activity (c). Thus, LGN cells are ideal for signaling changes in illumination, such as those that arise from stimulus edges.

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Pioneers in the Visual Cortex (continued) Light stimulus

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FIGURE 2 Simple cells in the primary visual cortex can be formed by the linking of outputs from concentric lateral geniculate nucleus (LGN) cells with adjacent receptive fields. In addition to signaling the presence of an edge, simple cells are selective for orientation. The simple cell illustrated here is either excited or inhibited by an edge that follows its preferred orientation. It shows no change in activity if the edge is at a perpendicular orientation.

light falls within the excitatory center region, the cell is activated. If the same spot is moved into the surrounding region, the activity is inhibited. A stimulus that encompasses both the center and the surrounding region will fail to activate the cell, because the activity from the excitatory and inhibitory regions will cancel each other out. This observation clarifies a fundamental principle of perception: Thenervous system is most interested in change. Werecognize an elephant not by the homogeneous gray surface of its body, but by the contrast of the gray edge of its shape against the background. In Figure 2, outputs from three LGN cells with receptive fields centered at slightly different positions are linked to a single cortical neuron. This cortical neuron would continue to have a center–surround organization, but for this cell the optimal stimulus would have to be an edge. In addition, the cell would be selective for edges in a certain orientation. As the same stimulus was rotated within the receptive field, the cell would cease to respond, because the edge would now span excitatory and inhibitory regions of the cell. Hubel and Wiesel called these cells simple cells, because their simple organization would extract a

fundamental feature for shape perception: the border of an object. The same linking principle can yield more complex cells—cells with a receptive-field organization that makes them sensitive to other features, such as corners or edgeterminations. Orientation selectivity has proved to be a hallmark of neurons in the primary visual cortex. Across a chunk of cortex measuring 2 mm by 2 mm, the receptive fields of neurons are centered on a similar region of space (Figure3). Within the chunk, the cells vary in terms of their preferred orientation, and they alternate between columns that are responsive to inputs from the right and left eyes. Aseries of such chunks allows for the full representation of external space, providing the visual system with a means of extracting the visible edges in ascene. Hubel and Wiesel’s studies established how a few organizational principles can serve as building blocks of perception derived from simple sensory neurons. The importance of their pioneering studies was acknowledged in 1981, when they shared the Nobel Prize in Physiology orMedicine.

Vision | 193

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b FIGURE 3 Feature representation within the primary visual cortex. (a) As the recording electrode is moved along the cortex, the preferred orientation of the cells continuously varies. The preferred orientation is plotted as a function of the location of the electrode. (b) The orientation columns are crossed with ocular dominance columns to form a cortical module. Within a module, the cells have similar receptive fields (location sensitivity), but they vary based on input source (left or right eye) and sensitivity to orientation, color, and size. For example, the so-called blobs contain cells that are sensitive to color and finer details in the visual input. This organization is repeated for each module.

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The same logic was used to design the motion experiment. For On Light stimulus this study, the control stimulus conDirection of sisted of a complex black-and-white movement collage of squares (Figure 5.27b). The same stimulus was used in the experimental condition, except that the squares were set in motion. They would move in one direction for 5 seconds and then in the reverse direction for the next 5 seconds. The results of the two studies provided clear evidence that the two tasks activated distinct brain regions (Figure 5.28). After subtracting activation during viewing of the achromatic collage, investigators found numerous residual foci of activation when participants a viewed the colored collage. These foci were bilateral and located in 100 the most anterior and inferior regions of the occipital lobe (Figure 75 5.28a). Although the spatial resolution of PET is coarse, these areas 50 were determined to be in front of the striate (V1) and prestriate (V2) cortex. In contrast, after the ap25 propriate subtraction in the motion experiment, the residual foci were 0 bilateral but near the junction of 0.5 1 2 4 8 16 32 64 128 256 512 the temporal, parietal, and occipital Speed (degrees/s) b cortices (Figure 5.28b). These foci FIGURE 5.26 Direction and speed tuning of a neuron from area MT. were more superior and much more (a) A rectangle was moved through the receptive field of this cell in various directions. The lateral than the color foci. red traces beside the stimulus cartoons indicate the responses of the cell to these stimuli. In Zeki and his colleagues were the polar graph, thefiring rates are plotted; the angular direction of each point indicates the stimulus direction, and the distance from the center indicates the firing rate as a percentage so taken with this dissociation of the maximum firing rate. The polygon formed when the points are connected indicates that they proposed applying the that the cell was maximally responsive to stimuli moved down and to the left; the cell renomenclature developed by prisponded minimally when the stimulus moved in the opposite direction. (b) This graph shows mate researchers here. They laspeed tuning for a cell in MT. In all conditions, the motion was in the optimal direction. This beled the area activated in the cell responded most vigorously when the stimulus moved at 64°/s. color foci as area V4 and the area activated in the motion task color patch was matched in luminance to its correspondas V5. Note that researchers frequently refer to area ing gray patch. With this setup, neurons sensitive to luV5 as human area MT, even though the area is not in minance information should be equally activated in conthe temporal lobe in the human brain. Of course, with trol and experimental conditions. The colored stimulus, PET data we cannot be sure that the foci of activation however, should produce more activity in neural regions really consist of just one visual area. sensitive to chromatic information. These regions should A comparison of Figures 5.25 and 5.28 reveals strikbe detected if the metabolic activity recorded when paring between-species differences in the relative position of ticipants viewed the gray stimulus is subtracted from the color and motion areas. For example, human MT is the activity recorded when participants viewed the color on the lateral surface of the brain, whereas the monkey stimulus. MT is more medial. Such differences probably exist beReceptive field

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problem, vision scientists prefer to work with flat maps of the brain. High-resolution anatomical MRI scans are obtained, and computer algorithms transform the folded, cortical surface into a two-dimensional map by tracing the gray matter. The activation signals from the fMRI study are then plotted on the flattened surface, and areas that were activated at similar times are color-coded. Researchers have used this procedure to reveal the organization of the human visual system in exquisite detail. Activation maps, plotted on both a normal brain and as flattened maps, are shown in Figure 5.30. In the flat maps, primary visual cortex (V1) lies along the calcarine sulcus. As in all physiological studies, the physical world is inverted. Except for the most anterior aspects of visual cortex, areas above the sulcus are active when the rotating stimulus is in the lower quadrant; the reverse is true when the stimulus is in the upper quadrant. Moreover, the activation patterns show a series of repetitions across

b FIGURE 5.27 Stimuli used in a PET experiment to identify regions involved in color and motion perception. (a) For the color experiment, the stimuli were composed of an arrangement of rectangles that were either shades of gray (control) or various colors (experimental). (b) For the motion experiment, a random pattern of black and white regions was either stationary (control) or moving (experimental).

cause the surface area of the human brain is substantially larger, and this expansion required additional folding of the continuous cortical sheet. The activation maps in Zeki’s PET study are rather crude. Vision scientists now employ sophisticated fMRI techniques to study the organization of human visual cortex. In these studies, a stimulus is systematically moved across the visual field (Figure 5.29). For example, a semicircular checkerboard pattern is slowly rotated about the center of view. In this way, the blood oxygen level– dependent (BOLD) response for areas representing the superior quadrant will be activated at a different time than areas representing the inferior quadrant—and in fact, the representation of the entire visual field can be continuously tracked. To compare areas that respond to foveal stimulation and those that respond to peripheral stimulation, researchers use a dilating and contracting ring stimulus. By combining these different stimuli, they can measure the cortical representation of external space. Due to the convoluted nature of the human visual cortex, the results from such an experiment would be difficult to decipher if we were to plot the data on the anatomical maps found in a brain atlas. To avoid this

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FIGURE 5.28 Regions of activation when the control conditions were subtracted from the experimental conditions in the experiment illustrated in Figure 5.27. (a) In the color condition, the prominent activation was medial, in areas corresponding to humanV4. (b) In the motion condition, the activation was more lateral, in areas corresponding to human MT. The foci also differed along the dorsoventral axis: The slice showing MT is superior to that showing V4. (c) Both stimuli produced significant activation in primary visual cortex, when compared to a control condition in which there was no visual stimulation.

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Mirror

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MRI scanner FIGURE 5.29 Mapping visual fields with functional magnetic resonance imaging (fMRI). The subject views a rotating circular wedge while fMRI scans are obtained. The wedge passes from one visual quadrant to the next, and the blood oxygenation level–dependent (BOLD) response in visual cortex is measured continuously to map out how the regions of activation change in a corresponding manner.

the visual cortex indicating distinct topographic maps. Following the conventions adopted in the single-cell studies in monkeys, the visual areas are numbered in increasing order, where primary visual cortex (V1) is most posterior and secondary visual areas (V2, V3/VP, V4) more anterior. Functional MRI mapping procedures can reveal multiple visual areas and can be used for comparison with the data obtained in work with monkeys. Within lateral occipital cortex (LOC), two subareas, LO1 and LO2, are evident. These regions had not been identified in previous studies of the monkey, and they provide further evidence of the expansion of visual cortex in humans (Figure 5.30). Interestingly, although activity in these areas is not modulated by motion per se, the regions do show an increase in the BOLD response when motion signals define object boundaries (e.g., a moving stimulus occludes the background) as well as when viewing displays of objects compared to scrambled images. Figure 5.30b also shows how eccentricity, the distance away from the fixation point, is also represented in these visual areas. Eccentricity refers to the radial distance from the center of vision (the foveal region) to the periphery. The cortical representation of the fovea, the regions shown in purple, pink, and red, is quite large. Visual acuity is much

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FIGURE 5.30 Two retinotopic areas in human lateral occipital cortex (LOC). (a) The circular displays at the bottom represent the display on which a stimulus was projected, with the person instructed to fixate at the center of the crosshair. Across the scanning run, the position of the stimulus spans visual space. Left side shows color coding of activation patterns on flat map of visual cortex when the angular position of a stimulus was varied. For example, areas responding when the stimulus was presented below fixation are coded as red. Multiple retinotopic maps are evident in dorsal and ventral regions. Right side shows color coding of activation patterns when the eccentricity of the stimulus was varied (e.g., dark purple indicates activation areas when stimulus was at center of fixation). (b) Position of visual areas shown in (a) on an inflated brain. The size and location can only be approximated in a lateral view of the 3-d image.

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From Sensation to Perception | 197 greater at the fovea due to the disproportionate amount of cortex that encodes information from this part of space. As we discussed in Chapter 3, technology marches on, and even more powerful tools are constantly being developed to provide better images of brain function. In the MRI world, stronger magnets improve the resolution of the fMRI signal. A 7-tesla (T) fMRI system is capable of providing detailed pictures of organizational principles within a visual area (Yacoub, 2008). Within V1, a 7-T magnet can reveal ocular dominance columns whose areas have similar retinotopic tuning, thus showing a preference for input from either the right or left eye. A shift across voxels in terms of orientation tuning is also visible. Such specificity is striking when we keep in mind that the activation within a voxel reflects the contribution of millions of neurons. Orientation tuning does not mean that all of these neurons have similar orientation preferences. Rather, it means that the relative contribution of orientation-selective neurons varies across voxels. Some voxels have a stronger contribution from vertically oriented cells; others, a stronger contribution from horizontally oriented cells (Figure 5.31).

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TAKE-HOME MESSAGES ■

The visual cortex is made up of many distinct regions. These regions are defined by their distinct, retinotopic maps. The visual areas have functional differences that reflect the types of computations performed by cells within the areas. For instance, cells in area V4 are sensitive to color information, and cells in V5 are sensitive to motion information. Humans also have visual areas that do not correspond to any region in our close primate relatives.

From Sensation to Perception In Chapter 6, we will explore the question of how our sensory experiences are turned into percepts—how we take the information from our sensory systems and use it to recognize objects and scenes. Here we briefly discuss the relationship between sensation and perception, describing experiments that ask how activation in early sensory areas relates to our perceptual experience. For example, is activation in early visual cortex sufficient to support perception? Or does that information have to be relayed to higher visual areas in order for us to recognize the presence of a stimulus? We have seen in the previous section that certain elementary features are represented in early sensory areas, usually with some form of topographic organization. Cells

FIGURE 5.31 High field resolution of human visual cortex. (a) Selected region of interest (ROI) in primary visual cortex targeted with a 7T MRI scanner. (b) At this resolution, it is possible to image ocular dominance columns, with red indicating areas that were active when the stimulus was presented to the right eye and blue areas that were active when the stimulus was presented to the left eye. (c) Orientation map in the ROI. Colors indicate preference for bars presented at different angles.

in auditory cortex are tuned to specific frequency bands; cells in visual cortex represent properties such as orientation, color, and motion. The information represented in primary sensory areas is refined and integrated as we move into secondary sensory areas. An important question is: At what stage of processing does this sensory stimulation become a percept, something we experience phenomenally?

Where Are Percepts Formed? One way to study this question is to “trick” our sensory processing systems with stimuli that cause us to form

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percepts that do not correspond to the true stimuli in the environment. In other words, what we perceive is an illusion. By following the processing of such stimuli using fMRI, we can attempt to determine where in the processing stream the signals become derailed. For instance, if we look at a colored disc that changes color every second from red to green, we have no problem seeing the two colors in succession. If the same display flips between the two colors 25 times per second (or 25 Hz), however, then the percept is of a fused color—a constant, yellowish white disc (the additive effects of red and green light). This phenomenon is known as flicker fusion. At what stage in the visual system does the system break down, failing to keep up with the flickering stimulus? Does it occur early in processing within the subcortical structures, or is it later, in one of the cortical visual areas? Using a flickering stimulus, Sheng He and colleagues tested participants while observing the changes in visual cortex (Jiang et al., 2007). In Figure 5.32, compare the fMRI BOLD responses for visual areas V1, V4, and VO during a 5-Hz full-contrast flicker condition (perceptually two colors), a 30-Hz full-contrast flicker condition (perceptually one fused color), and a control condition, which was a 5-Hz subthreshold contrast condition (perceptually indistinguishable from the 30-Hz flicker). Subcortical processing and several of the lower cortical processing areas, V1 and V4, were able to distinguish between the 5-Hz flicker, the 30-Hz flicker, and the 5-Hz nonflickering control. In contrast, the BOLD response within a visual area just adjacent to V4, VO, did not differentiate between the high-flicker stimulus and the static control stimulus (Figure 5.32). We can conclude that the illusion—a yellowish object that is not flickering—is formed in this higher visual area (known variously as either VO or V8), indicating that although the information is sensed accurately at earlier stages within the visual stream, conscious perception, at least of color, is more closely linked to higher-area activity. In a related study, John-Dylan Haynes and Geraint Rees at the University College London asked if fMRI could be used to detect the neural fingerprints of unconscious “perception” (Haynes & Rees, 2005). Participants were asked to decide which of two ways a stimulus was oriented (Figure 5.33). When shown the stimulus for just a 20th of a second, people can identify its orientation with a high degree of accuracy. If, however, the stimulus is presented even faster—say, for just a 30th of a second—and it is preceded and followed by a mask of crosshatched lines, performance drops to chance levels. Nonetheless, by using a sophisticated pattern recognition algorithm on the fMRI data, the researchers were able to show that activity in V1 could distinguish which stimulus had been presented—an effect that was lost in V2 and V3.

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FIGURE 5.32 Imaging the neural correlates of perception. (a) Flickering pinwheel stimulus for studying limits of temporal resolution. The left and right stimuli alternated at different rates or contrast. (b) BOLD response to the flickering stimuli in three visual areas, V1, hV4, and VO. The activation profile in VO matches the participants’ perceptual experience since the color changes in the stimulus were invisible at the high 30 Hz rate or when the contrast was below threshold. In contrast, the activation profile in V1 and hV4 is correlated with the actual stimulus when the contrast was above threshold.

As the preceding examples indicate, our primary sensory regions provide a representation that is closely linked to the physical stimulus, and our perceptual experience is more dependent on activity in secondary and association sensory regions. Note, though, that the examples base this argument on the fact that the absence of a perceptual experience was matched by the absence of detectable activity in secondary regions. We can also consider the flip side of the coin, by asking what brain regions show

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15 s FIGURE 5.33 Activity in V1 can predict orientation of an invisible stimulus. (a) Participants viewed an annulus in which the lines were either oriented in only one direction (target) or both directions (mask). (b)In some trials, the target was presented for only 17 ms and was preceded by the mask. On these trials, the target was not visible to the participant. A pattern classifier was used to predict from the fMRI data if the target was oriented to the left or right. When the stimulus was visible, the classifier was very accurate when using data from V1, V2, or V3. When the stimulus was invisible due to the mask, the classifier only achieved above chance performance for the data from V1.

activation patterns that are correlated with illusory percepts. Stare at the Enigma pattern in Figure 5.34. After a few seconds, you should begin to see scintillating motion within the blue circles—an illusion created by their opposed orientation to the radial black and white lines. What are the neural correlates of this illusion? We know that moving patterns produce a strong hemodynamic response in V5. Is this same area also activated during illusory motion? Both PET and fMRI have been used to show that viewing displays like the Enigma pattern does indeed lead to pronounced activity in V5. This activation is selective: Activity in V1 does not increase during illusory motion. An even stronger case for the hypothesis that perception is more closely linked to secondary sensory areas would require evidence showing that activity in these areas can be sufficient, and even predictive of perception. This idea was tested in a remarkable study performed by Michael Shadlen and his colleagues at the University of Washington (Ditterich et al., 2003). They used a reverse engineering strategy to manipulate activation patterns in sensory cortex. As we noted earlier, physiologists usually eavesdrop on

neurons in sensory cortex using electrodes that probe how cells respond to information in the environment. The same electrodes can also be used to activate cells. When a current passes through the electrode, neurons near the tip of the electrode are activated. In the Shadlen study, researchers used this method to measure motion perception. Monkeys were trained to make an eye movement, indicating the perceived direction of a patch of moving dots (Figure 5.35). To make the task challenging, only a small percentage of the dots moved in a common direction; the rest moved in random directions. The researchers then recorded from a cell in area MT. After determining the directional tuning of that cell, they passed a current through the electrode while the stimulus was present. This manipulation increased the probability that the monkey would report that the stimulus was moving in the cell’s preferred direction (Figure 5.35). Note that the electrical current, at least with this method, will likely induce activity in many neurons. Nonetheless, the finding that the animal’s percept was altered suggests that neighboring cells have similar direction-tuning properties, consistent with a topographic representation of motion direction in MT. Of course, with the monkeys, we can only infer their perception from behavior; it is problematic to infer that these percepts correspond to conscious experience. Similar stimulation methods have been used on rare occasions in humans during intraoperative surgical procedures. In one such procedure, electrodes were positioned along the ventral regions of visual cortex (Murphey et al., 2008). This region includes at least two areas that are known to be involved with color processing: the posterior center in the lingual gyrus of the occipital lobe (V4) and

FIGURE 5.34 The Enigma pattern: a visual illusion. When viewing the Enigma pattern, we perceive illusory motion. Viewing the pattern is accompanied by activation in area MT.

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the anterior center in the medial fusiform gyrus of the temporal lobe, which has been labeled V4a. When used as recording devices, electrodes in either area responded in a selective manner to chromatic stimuli. For example, the activity at one location was stronger to one color as compared to another. Even more interesting was what happened when the electrodes were used as stimulating devices. In the anterior color region, stimulation led to the patient reporting seeing a colored, amorphous shape. Moreover, the color of the illusion was similar to the preferred color for that site. Thus, in this higher visual area, there was a close correspondence between the perception of a color when it was elicited by a visual stimulus and when the cortex was electrically stimulated.

Individual Differences in Perception Occasionally, when viewing illusions with a friend, you will find that the two of you don’t have the same reaction. You might be saying, “This is crazy!” Mean-

FIGURE 5.35 Activation of MT neurons influences the perceived direction of motion. (a) Trial sequence. Two red dots indicate possible directions of motion (up and to the right or downward). In 50% of the trials, electrical stimulation was briefly applied in area MT when the stimulus was presented. The stimulation was directed at neurons with a known preferred direction. After the stimulus, the monkey looks at one of the two red dots to indicate the perceived direction of motion. (b) When the stimulus was present, the monkey was more likely to respond that the direction of motion was in the direction of the preferred direction of the electrically stimulated cells. The x-axis indicates the strength of the motion signal, with 0% indicating random motion, negative values indicate motion in the opposite direction of the cell’s preferred direction, and positive values motion in the direction of the cell’s preferred direction. Larger values mean more of the dots moved in the indicated direction.

while, your friend is shrugging her shoulders, wondering what you are seeing. Although we commonly accept the idea that people have different emotional reactions to similar situations, we tend to assume that everyone perceives the same things. In this example, we might assume your friend just doesn’t know how to “look” at the display in the right way. To test this assumption, researchers sought to identify neural biomarkers that might account for individual differences in perception (Schwarzkopf et al., 2011). Figure 5.36 shows one of the classic illusions in visual perception: the Ebbinghaus illusion, devised by Hermann Ebbinghaus (1850–1909), a German pioneer in experimental psychology. Compare the size of the two circles in the middle of the displays on the left and right. Does one look larger than the other? By how much? Everyone sees the middle circle on the right as larger than the one on the left, but people vary considerably regarding how much larger they think the circle is. Some individuals see the right inner circle as larger by only about 10 %. For others, the illusion is close to 50 %. These differences

Deficits in Visual Perception | 201 studies. In 1888, Louis Verrey (cited in Zeki, 1993), described a patient who, after suffering a stroke, had lost the ability to perceive colors in her right visual field. Verrey reported that while the patient had problems with acuity within restricted portions of this right visual field, the color deficit was uniform and complete. After his patient’s death, Verrey performed an autopsy. What he found led him to conclude there was a “centre for the chromatic sense” (Zeki, 1993) in the human brain, which he located in the lingual and fusiform gyri. We can guess that this patient’s world looked similar to the drawing in Figure 5.37: On one side of space, the world was multicolored; on the other, it was a montage of grays. FIGURE 5.36 Strength of a visual size illusion is correlated with size of V1. Compare the size of the center circle in the two images. People see the one on the right as larger, an illusion first described by Ebbinghaus. Across individuals, the strength of the illusion is correlated with the size of V1.

are quite reliable and can be observed across a range of size illusions, leading the research team to wonder about their underlying cause. They used fMRI to identify retinotopic areas and then measured the size of the functionally defined area. Remarkably, they observed a negative correlation between the size of the illusion and the size of V1. The smaller the area of V1, the larger the perceived illusion. This correlation was not found with V2 or V3. Why might people with a larger V1 show a smaller illusion? One hypothesis is that with a large visual cortex, each region of space has a better representation. A corollary of this is that each region of space is less likely to be influenced from neighboring regions of space. Hence, in the Ebbinghaus illusion, the neighboring circles have less influence on the central circle when a larger V1 provides a higher-resolution representation of space. Perception, then, is in the brain anatomy of the beholder. To try out more fascinating illusions, go to http:// www.michaelbach.de/ot/.

Deficits in Color Perception: Achromatopsia When we speak of someone who is color-blind, we are usually describing a person who has inherited a gene that produces an abnormality in the photoreceptor system. Dichromats, people with only two photopigments, can be classified as red–green color-blind if they are missing the photopigment sensitive to either medium or long wavelengths, or blue–yellow color-blind if they are missing the short-wavelength photopigment. Anomalous trichromats, in contrast, have all three photopigments, but one of the pigments exhibits abnormal sensitivity. The incidence of these genetic disorders is high in males: about 8 % of the population. The incidence in females is less than 1 %. Much rarer are disorders of color perception that arise from disturbances of the central nervous system. These disorders are called achromatopsia (from the prefix a−, “without,” and the stem chroma, “hue”). J. C. Meadows (1974)

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Our percepts are more closely related to activity in higher visual areas than to activity in primary visual cortex. Anatomical differences among people in the size of V1 affect the extent of visual illusion.

Deficits in Visual Perception Before the advent of neuroimaging, much of what we learned about visual processing in the human brain came from lesion

FIGURE 5.37 People with achromatopsia see the world as devoid of color. Because color differences are usually correlated with brightness differences, the objects in a scene might be distinguishable and appear as different shades of gray. This figure shows how the world might look to a person with hemiachromatopsia. Most of the people who are affected have some residual color perception, although they cannot distinguish between subtle color variations.

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of the National Hospital for Neurology and Neurosurgery in London described one such patient as follows: Everything looked black or grey [Figure 5.37]. He had difficulty distinguishing British postage stamps of different value, which look alike, but are of different colors. He was a keen gardener, but found that he pruned live rather than dead vines. He had difficulty distinguishing certain foods on his plate where color was the distinguishing mark. (p. 629) Patients with achromatopsia often report that colors have become a bland palette of “dirty shades of gray.” The shading reflects variations in brightness rather than hue. Other aspects of vision, such as depth and texture perception, remain intact, enabling someone with achromatopsia to see and recognize objects in the world. Indeed, color is not a necessary cue for shape perception. The subtlety of color perception is underscored when we consider that people often do not notice the change from black and white to color when Dorothy lands in Oz in the movie The Wizard of Oz. Nonetheless, when lost forever, this subtlety is sorely missed. Achromatopsia has consistently been associated with lesions that encompass V4 and the region anterior to V4. The lesions, however, typically extend to neighboring regions of the visual cortex. Color-sensitive neurons

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are also orientation selective; as such, many achromatic patients have difficulty with form perception. The hypothesis linking achromatopsia with deficits in form perception was carefully explored in the case study of a patient who suffered a stroke resulting in a small lesion near the temporo-occipital border in the right hemisphere. The damage was centered in area V4 and anterior parts of the visual cortex (Figure 5.38a). To assess the patient’s achromatopsia, a hue-matching experiment was performed in which a sample color was presented at the fovea, followed by a test color in one of the four quadrants of space. The patient’s task was to judge if the two colors were the same. The difference between the sample and test color was adjusted until the patient was performing correctly on 80 % of the trials, and this difference was measured separately for each quadrant. Regardless of the sample hue, the patient was severely impaired on the hue-matching task when the test color was presented in the upper left visual field (Figure 5.38b). The fact that the deficit was found only in the upper contralesional visual field is consistent with previous reports of achromatopsia. The next order of business was to examine shape perception. Would the patient show similar deficits in shape perception in this quadrant? If so, what types of shape perception tasks would reveal the impairment? To

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FIGURE 5.38 Color and shape perception in a patient with a unilateral lesion of V4. (a) MRI scans showing a small lesion encompassing V4 in the right hemisphere. (b) Color perception thresholds in each visual quadrant. The patient was severely impaired on the huematching task when the test color was presented to the upper left visual field. The y-axis indicates the color required to detect a difference between a patch shown in each visual quadrant (UL = upper left, LL= lower left, UR = upper right, LR = lower right) and the target color shown at the fovea. The target color was red for the results shown in the top panel and green for the results shown in the bottom panel.

Deficits in Visual Perception | 203 answer these questions, a variety of tasks were administered. The stimuli are shown in Figure 5.39. On the basic visual discriminations of contrast, orientation, and motion, the patient’s performance was similar for all four quadrants and comparable to the performance of control participants. He showed impairment on tests of higher order shape perception, however; and again, this impairment was restricted to the upper left quadrant. For these tasks, shape information requires combining information from neurons that might detect simple properties such as line orientation. For example, the orientation of the line separating the two semicircles (Figure 5.39d) is defined only by the combination of the lengths of the individual stripes and their offset. Characterizing area V4 as a “color” area is too simplistic. This area is part of secondary visual areas devoted to shape perception. Color can provide an important cue about an object’s shape. V4 may be invaluable for using color information as one cue to define the boundaries that separate the objects that form our visual environment. Revisiting patient P.T. Let’s return to patient P.T., who we met at the beginning of the chapter. Recall that he had difficulty recognizing familiar places and objects follow-

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FIGURE 5.39 Tests of form perception. Stimuli used to assess form perception in the patient with damage to area V4 illustrated in Figure 5.38. On basic tests of luminance (a),orientation (b), and motion (c), the patient’s perceptual threshold was similar in all four quadrants. Thresholds for illusory contours (d)and complex shapes (e) were elevated in the upper left quadrant.

ing a stroke to his right hemisphere. Further examination revealed some puzzling features of his perceptual deficits. P.T. was shown two paintings: one by Monet, depicting a subdued 19th-century countryman dressed in his Sunday suit; the other by Picasso, of a woman with a terrified expression (Figure 5.40). P.T. was asked to describe what he saw in each painting. When shown the Monet, he looked puzzled. He saw no definable forms, just an abstract blend of colors and shapes. His problem in interpreting the painting was consonant with the deficits he experienced at home. Yet he readily identified the figure in Picasso’s painting and pointed out that it was a woman, or perhaps a young girl. This dissociation is compelling, for most would readily agree that the Monet is more realistic. Picasso painted the parts of his work as separate units. He used sharp contrasts in brightness and vivid colors to highlight facial regions. Monet opted for a softer approach, in which parts are best seen in a continuous whole, with gradual changes in contrast and color. Can any of these factors account for P.T.’s performance in identifying the figures in Picasso and Monet? The neurologist evaluating P.T. emphasized that the primary problem stemmed from a deficit in color perception. This hypothesis is in accord with one of the primary differences between the Monet and the Picasso. In the Monet painting, the boundaries between the face and the background are blended: Gradual variations in color demarcate the facial regions and separate them from the background landscape. A deficit in color perception provided a parsimonious account of the patient’s problems in recognizing faces and landscapes. The rolling green hills of an Oregon farm can blur into a homogeneous mass if a person cannot discern fine variations in color. In a similar way, each face has its characteristic coloration. It seems equally plausible, however, that the problem stemmed from a deficit in contrast or contour perception. These features are salient in the Picasso and absent in the Monet. Indeed, we know from our recent discussion of V4 that color and shape perception are often conflated. It is clear that the patient’s stroke affected primarily the cortical projections of the pathways essential for color and form perception. In contrast, the cortical projections of the pathway involved in motion were intact. The patient had no trouble recognizing his wife as she moved from the stove to the kitchen table; indeed, P.T. commented that her idiosyncratic movement enabled him to recognize her.

Deficits in Motion Perception: Akinetopsia In 1983, researchers at the Max Planck Institute in Munich reported a striking case of a woman who had incurred

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a selective loss of motion perception, or akinetopsia (Zihl et al., 1983). For this woman, whom we call M.P., perception was akin to viewing the world as a series of snapshots. Rather than seeing things move continuously in space, she saw moving objects appear in one position and then another. When pouring a cup of tea, M.P. would see the liquid frozen in air, like a glacier. She would fail to notice the tea rising in her cup and would be surprised when the cup overflowed. The loss of motion perception also made M.P. hesitant about crossing the street. As she noted, “When I’m looking at the car first, it seems far away. But then, when I want to cross the road, suddenly the car is very near” (Zihl et al., 1983, p. 315). Examination revealed M.P.’s color and form perception to be intact. Her ability to perceive briefly presented objects and letters, for example, was within the normal range. Nonetheless, her ability to judge the direction and speed of moving objects was severely impaired. This deficit was most apparent with stimuli moving at high speeds. At speeds faster than 20°/s, M.P. never reported detecting the motion. She could see that a dot’s position had changed and hence could infer motion. But her percept was of two static images; there was no continuity from one image to the other. Even when presented with stimuli moving more slowly, M.P. was hesitant to report a clear impression of motion. CT scans of M.P. revealed large, bilateral lesions involving the temporoparietal cortices. On each side, the lesions included posterior and lateral portions of the middle temporal gyrus. These lesions roughly corresponded to areas that participate in motion perception. Furthermore, the lesions were lateral and superior to human V4, including the area identified as V5, the human equivalent of area MT (Figure 5.41).

FIGURE 5.40 Two portraits. (a) Detail from Luncheon on the Grass, painted in the 1860s by the French Impressionist Claude Monet. (b) Pablo Picasso’s Weeping Woman, painted in 1937 during his Cubist period. © 2008 Estate of Pablo Picasso/Artists Right Society (ARS), New York.

Although the case of M.P. has been cited widely for many years, the fact that similar patients have not been identified suggests that severe forms of akinetopsia result only from bilateral lesions. With unilateral lesions, the motion perception deficits are much more subtle (Plant et al., 1993). Perhaps people can perceive motion as long as human V5 is intact in at least one hemisphere. Motion, by definition, is a dynamic percept, one that typically unfolds over an extended period of time. With longer viewing times, signals from early visual areas in the impaired hemisphere have an opportunity to reach secondary visual areas in the unimpaired hemisphere. The receptive fields in primate area V5 are huge and have cells that can be activated by stimuli presented in either visual field. Still, the application of transcranial magnetic stimulation (TMS; see Chapter 3) over human V5 can produce transient deficits in motion perception. In one such experiment, participants were asked to judge whether a stimulus moved up or down (Stevens et al., 2009). To make the task demanding, the displays consisted of a patch of dots, only some of which moved in the target direction; the rest moved in random directions. Moreover, the target was preceded and followed by “masking” stimuli in which all of the dots moved in random directions. Thus, the stimulus direction was visible during only a brief 100-ms window (Figure 5.42). TMS was applied over either V5 or a control region, the motor cortex. Performance of the motion task was disrupted by stimulation over V5, creating a transient form of akinetopsia. One feature of TMS that makes it such an excellent research tool is that investigators can vary the timing of

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the magnetic pulses to determine the time of maximum disruption. Knowing when a disruption occurs can help locate where it is occurring. To the researchers’ surprise, TMS disrupted performance at two distinct intervals. One was when the pulse was applied about 100 ms before the onset of the target stimulus. The second was approximately 150 ms after the onset of the target stimulus. This latter timing isn’t so surprising. It coincides with estimates of when activity within V5 would be important for integrating motion information to determine the direction of a moving stimulus. Thus, the researchers assumed that the pulses applied at this point in time added noise to the representations in V5. What was that first disruption, when the TMS pulse was delivered before the onset of the target stimulus? The phenomenon was puzzling. The deficit here is unlikely to be the direct result of a perturbation of V5 neurons, because if that were true, we should not see performance improve before falling off again. Two other hypotheses should be considered. First, TMS at this point might disrupt the observer’s attentional focus, making it hard to orient to the target stimulus. Second, TMS over V5 may not only cause neurons in V5 to fire but also trigger neural firing in V1 after a short delay. This second hypothesis is based on the understanding that cortical connectivity and processing along sensory pathways, and indeed, across the cortex, are almost always bidirectional. Although models of visual perception tend to emphasize that processing proceeds from a primary region such as V1 to a secondary visual area such as V5, prominent pathways also are going in the reverse direction. Based on the second hypothesis, the first dip in performance is due to the indirect effect of the TMS pulse on V1 activity, and the second dip in performance is due to the direct effect of the TMS pulse on V5 activity. This observation is roughly consistent with the temporal pattern of activity observed in single-cell recordings in these two areas in response to moving stimuli.

Perception Without a VisualCortex Almost all of the ascending axons from the LGN terminate in the primary visual cortex. An individual with damaged primary visual cortex is expected to be blind; and indeed, this is what is observed. The blindness may be incomplete, however. If the lesion is restricted to one half of the visual field, the loss of perception will be restricted to the contralateral side of space; such a deficit is referred to as hemianopia. Smaller lesions may produce more discrete regions of blindness, or scotomas. Patients with primary visual cortex lesions are unable to report seeing anything presented within a scotoma. As anatomists have shown, however, the cortex includes not only multiple visual pathways but also prominent subcortical visual

pathways. These observations have led to some surprising findings showing that visual capabilities may persist even in the absence of the primary visual cortex.

Cortical and Subcortical Perception in the Hamster As mentioned previously, in humans about 90 % of the optic nerve fibers project to the LGN. The other 10 % project to other subcortical nuclei, and the most prominent projection is to the superior colliculus (SC). What’s more, the proportion of retinocollicular fibers is even larger in most other species. The SC plays a critical role in producing eye movements. If this midbrain structure becomes atrophied, as in a degenerative disorder such as supranuclear palsy, eye movements become paralyzed. Stimulation of neurons in the SC can also trigger eye movements; the direction of movement depends on the stimulation site. Observations like this emphasize an important motor role for the SC, but it is also interesting to ask about the representation of the visual world in the SC. What kinds of visual behaviors are possible from this system? Gerald Schneider (1969), at the Massachusetts Institute of Technology, provided an important insight into this question. Hamsters were trained to perform the two tasks illustrated in Figure 5.43. In one task, the hamsters were trained to turn their heads in the direction of a sunflower seed held in an experimenter’s hand (Figure 5.43a). The task was easy for hamsters because they have a strong propensity to find sunflower seeds and put them in their cheeks. The second task presented more of a challenge. Here the animals were trained to run down a two-armed maze and enter the door behind which a sunflower seed was hidden (Figure 5.43b). The task required the animals to make simple visual discriminations, such as distinguishing between black and white doors or between doors with vertical or horizontal stripes. For normal hamsters, the discriminations are not taxing. Within a few trials, they became proficient in selecting the correct door in almost all trials. After training, Schneider divided the hamsters into two experimental groups. One group received bilateral lesions of the visual cortex, including all of areas 17 and 18 (Figure 5.43c). For the second group, the superior colliculus was rendered nonfunctional by the ablation of its input fibers (Figure 5.43d). This strategy was necessary because direct lesions to the colliculus, which borders many brainstem nuclei that are essential for life, are likely to kill the animals. The two lesions yielded a double dissociation. Cortical lesions severely impaired the animals’ performance on the visual identification tasks. The animals could run down the maze and had sufficient motor capabilities to enter one of the doors, but they could not discriminate

Multimodal Perception: I See WhatYou’re Sayin’ | 207 black from white or horizontal from vertical stripes. In contrast, the animals with collicular lesions demonstrated no impairment on this task. On the sunflower seed localization task, the deficits were reversed. Animals with cortical lesions were perfect at this task once they had recovered from the surgery. Yet animals with collicular lesions acted as though they were blind. They made no attempt to orient toward the seeds—and not because they were unmotivated or had a motor problem. If the seed brushed against a whisker, a Orientation task b Discrimination task the animal rapidly turned toward it and gobbled it up. These data provide compelling evidence for dissociable functions of the hamsters’ superior colliculus and visual cortex. The collicular lesions impaired their ability to orient toward the position of a stimulus, and the cortical lesions disrupted visual acuity. c Lesion of colliculus d Lesion of visual cortex For the hamster, this double dissociation might be thought FIGURE 5.43 Double dissociation between lesions of the superior colliculus and visual cortex. of as reflecting two systems: (a) In the orientation task, hamsters were trained to collect sunflower seeds that were held at varione devoted to spatial orien- ous positions in space. (b) In the discrimination task, hamsters were trained to run down one of two alleys toward a door that had either horizontal or vertical stripes. (c) Lesions of the colliculus tation, the other devoted to disrupted performance on the localization task. (d) Lesions of the visual cortex selectively impaired object identification. As we performance on the discrimination task. will see in the next chapter, the idea that the representa■ These regions do not just represent color, however; they tion of the properties of a stimulus and its location may are also important for shape perception. Color is one entail different neural pathways is also an important attribute that facilitates the perception of shape. idea for understanding visual processing within the cor■ Akinetopsia, the inability to process motion, results from tex. We will return to the issue of residual perception lesions to area V5 (human MT). following damage to the primary visual cortex in Chap■ As with many neurological conditions, the deficit can be ter 14 when we turn to the question of consciousness. quite subtle for unilateral lesions.

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Superior colliculus lesions impair the ability of an animal to orient toward the position of a stimulus (which is important for spatial orientation); visual cortex lesions impair visual acuity (which is important for object identification). Achromatopsia, the inability to perceive color, results from lesions to areas in and around human V4.

Multimodal Perception: I See WhatYou’re Sayin’ Each of our senses gives us unique information about the world we live in. Color is a visual experience; pitch is uniquely auditory. Even though the information provided

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by each sense is distinct, the resulting representation of the surrounding world is not one of disjointed sensations, but of a unified multisensory experience. A meal in a restaurant is more than just the taste of the food. Restaurant owners know that the visual presentation of the food and the surroundings, the background noise or the lack of it, the comfort of the chairs, the fragrances from the kitchen, the interaction with the server, all contribute to how you will rate the restaurant’s cooking—that is, the combined experience of all the senses affects the taste of the food. How much of that experience happens because it is expected? If all else is perfect, you may rate the food better than it actually is because you expect it to be in line with your other sensations. Or, in contrast, even if you are served the most delicious fettuccine in the world, if the restaurant has the fragrance of cabbage, a 4-year-old is screaming and kicking in the booth behind you, and a rude server delivers your meal on a greasy plate, you most likely will not judge the pasta to be so great. Much of what we experience is what we expect to experience. At a Washington, D.C., metro station, most people don’t expect to hear a virtuoso. When the virtuoso Joshua Bell, clad in jeans and a T-shirt, propped open his violin case for change and played six classical masterpieces on one of the finest-sounding violins ever made—a 1713 creation by Antonio Stradivari—only a handful of the hundreds of commuters passing by stopped to listen. A few nights earlier, they would have had to pay over $100 to hear Mr. Bell perform at a nearby concert hall. With our eyes closed and nose pinched, if we are asked to bite into an “apple” and guess whether it is a Fuji or a Golden Delicious, most of us will say one or the other. We wouldn’t be able to tell, at least in the first bite, that we have been tricked into biting an onion. When you sit enthralled in a movie theater, staring up at the screen, you have the perception that the voices are coming from the actors. Nevertheless, the sounds are actually coming from the speakers located at the sides of the screen. How about the puppet sitting on the lap of the ventriloquist? We know that the ventriloquist is doing the talking, but we see the puppet moving his lips: We have the perception that it is the puppet who is talking. In both cases, the location of the auditory cue is “captured” by the location of the visual cue. We can study our sensory systems in isolation, but perception is really a synthetic process, one in which the organism uses all available information to converge on a coherent representation of the world. A particularly powerful demonstration of the multimodal nature of perception comes from the world of speech perception. Most people think of speech as an inherently auditory process—we decipher the sounds of language to identify phonemes, combining these into

words, sentences, and phrases (see Chapter 11). Speech perception can certainly occur if the input is limited to audition: We can readily understand a friend over the phone, and people who are congenitally blind learn to speak with minimal difficulty. If you are learning a new language, however, then that phone conversation is notoriously more difficult than if the conversation is face-to-face: The sounds we hear can be influenced by visual cues. This principle has been shown in what has come to be called the McGurk effect, in which the perception of speech— what you believe that you “hear”—is influenced by the lip movements that your eyes see. Examples of this compelling visual-auditory illusion can be found at www.youtube .com/watch?v=G-lN8vWm3m0. Cross-modal capture effects aren’t limited to interactions between vision and audition. We can even be fooled into misidentifying an inanimate object as part of our body. In the rubber hand illusion, a rubber left hand is placed in a biologically plausible position on a table in full view of the subject, while her real left arm and hand are blocked from her view by a screen (see http://www. youtube.com/watch?v=TCQbygjG0RU). The researcher then runs a brush over the person’s hand (still blocked from her view) while performing the same action with a different brush in the corresponding direction over the rubber hand that the subject sees. After a couple of minutes, she will “feel” that the rubber hand is her own. If blindfolded and asked to point to her hand, she will point to the rubber hand rather than her own. Even more dramatic, if the experimenter suddenly reaches out and hits the rubber hand with a hammer, she is likely to scream. These illusions work because they take advantage of correlations that are generally present between the senses in day-to-day life. The gestures of a speaker’s lips normally conform to the sounds we hear; when we see something close to our hand and feel something touching our hand, we correctly assume they are one and the same. It is only through the illusion that the processing can be teased apart and we realize that information from different sensory systems have been integrated in our brain.

Multimodal Processing in the Brain How Does It Happen? How does the brain integrate information from the different senses to form a coherent percept? An older view was that some senses dominated others. In particular, vision was thought to dominate over all of the other senses, as in the examples given earlier. A more recent alternative is that the brain combines the input from multiple sensory systems about a particular external property (e.g., the location of a sound or touch), weighs the reliability of each sense, and makes

Multimodal Perception: I See WhatYou’re Sayin’ | 209 In animal studies, neurophysiological methods have been especially useful: Once an electrode has been placed in a targeted brain region, the animal can be presented with a range of stimuli to see if, and by what, the region is activated. For instance, when exploring visual responses, the researcher might vary the position of the stimulus, or its color or movement. To evaluate multisensory processing, the researcher can present stimuli along different sensory channels, asking not only if the cell responds to more than one sense but also about the relationship between the responses to stimuli from different senses. FIGURE 5.44 The McGurk effect.

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an estimate, a decision, from this information about the external property in question. In this view, visual capture occurs because the brain judges visual information in most circumstances to be the most reliable and thus, gives it the most weight. The system is flexible, however, and the context can lead to a change in how information is weighed. When walking in the woods at dusk, we give more emphasis to somatosensory information as we step gingerly to avoid roots or listen carefully for breaking twigs that might signal that we’ve wandered off the path. It appears that other considerations are factored in and tip the weighting of information scales; in this case, the ambient light, or lack of it, favors the other senses. So, sometimes the visual system can be overruled. A compelling demonstration of this is shown by the finding that when a flash of light is paired with two beeps, participants perceive the light as having flashed twice (Shams, 2000). This illusion, known as auditory driving, differs some from our previous examples. Instead of all of the modalities passing on information about one external property (the puppet or the rubber hand), here the stimulation of one sense (the ear) appears to affect the judgment about a property typically associated with a different sense. Specifically, the auditory beeps create a context of two events, a feature that the brain then applies to the light, creating a coherent percept. How sensory processing is integrated between modalities is currently a hot topic. It includes the usual cast of questions: Where is information from different sensory systems integrated in the brain? Is it early or late in processing? What are the pathways that are involved?

Subcortical: Superior Colliculus. One well-studied multimodal site is the superior colliculus, the subcortical midbrain region that we discussed earlier in regard to eye movements. The superior colliculus contains orderly topographic maps of the environment in visual, auditory, and even tactile domains (Figure 5.45). Many cells in the superior colliculus show multisensory properties, being activated by inputs from more than one sensory modality. These neurons combine information from different sensory channels and integrate that information. In fact, the response of the cell is stronger when there are inputs from multiple senses compared to when the input is from a single modality (Stein, 2004). Such enhanced responses are most effective when a unimodal stimulus fails to produce a response on its own. In this way the combination of weak, even subthreshold, unimodal signals can be detected and cause participants to orient toward the stimulus. Multisensory signals are also treated

Caudal

Where Does It Happen? Brain regions containing neurons that respond to more than one sense are described as multisensory. Multisensory integration (Holmes & Spence, 2005) occurs at many different regions in the brain, both subcortically and cortically. Let’s look at some of the studies that have been exploring this question.

Multisensory FIGURE 5.45 The interaction of visual, auditory, and somatosensory spatial maps in the superior colliculus provides a representation of multisensory space.

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by the brain as more reliable than signals from a single sensory channel. A rustling sound in the grass could indicate the presence of a snake, or just the rising evening breeze. But if that sound is combined with a glimmer of something slithering along, you can bet the brain will generate a fast-response eye movement to verify the presence of a snake. Integration effects require that the different stimuli be coincident in both space and time. For example, if a visual event is spatially and temporally synchronous with a loud noise, as in the auditory driving example described earlier, the resulting multisensory response will be enhanced. If, however, the sound originates from a different location than the light, or is not temporally synchronized with the light, the response of the collicular cell will be lower than if either stimulus were presented alone. Such effects again demonstrate how the brain weights information in terms of its reliability. In the natural world, we have learned that visual and auditory cues are usually closely synchronized; we can learn that a distant visual event such as a flash of lightning will be followed by a crack of thunder. Because they are not coincident in time and space, however, our orienting system here will be driven by just one or the other, especially since these signals can be quite intense. Cortical Processing. Multisensory activity is also observed in many cortical regions. The superior temporal sulcus (STS) is known to have connections both coming from and going to the various sensory cortices. Neurophysiologists have identified cells in the STS of monkeys that respond to visual, auditory, and somatosensory stimuli (Hikosaka et al., 1988). Functional MRI has also been used to identify areas exhibiting multisensory areas of the cortex. The crude resolution of this technique makes it impossible to determine if the BOLD response reflects the activity of multisensory neurons or neighboring clusters of neurons that respond to a single modality. Researchers can build on the ideas of multisensory integration, however, to ask if the activation reflects the combination of different sensory cues. For example, the STS in the left hemisphere is active when people are actively engaged in lip-reading (something that we unconsciously use during normal speech comprehension), but not when the sounds are mismatched to the lip movements (Calvert et al., 1997). Other brain regions showing similar sensory integration effects include various regions of the parietal and frontal lobes, as well as the hippocampus (Figure 5.46). With careful study, we can actually see multisensory effects even in areas that are traditionally thought to be sensory specific. For instance, in one fMRI study, activation in

Posterior parietal Premotor cortex Posterior superior temporal sulcus

Inferior prefontal cortex

Trimodal (AVT) Audiovisual Visuotactile Visuotactile shape

PHOTO

Audiovisual face/voice Multisensory language FIGURE 5.46 Multisensory regions of the cerebral cortex. Areas of the left hemisphere that show increased BOLD response when comparing responses to unisensory and multisensory stimulation. A similar picture is evident in the right hemisphere.

auditory cortex was greater when the sounds were accompanied by simultaneous visual stimulation (Kayser et al., 2007). Given the slow rise time of the BOLD response, this increase may have been more of a preparatory response that treated the visual signals as a cue for sounds. Event-related potential (ERP) studies have found, however, that the very early visual component of the ERP wave is enhanced when the visual stimulus is presented close in space to a corresponding tactile stimulus (Kennett et al., 2001). Vincenzo Romei (2007) and his colleagues at the University of Geneva have sought to understand how early sensory areas might interact to support multisensory integration. Participants in one of their studies were required to press a button as soon as they detected a stimulus. The stimulus could be a light, a sound, or both. To disrupt visual processing, the researchers applied a TMS pulse over the visual cortex just after the stimulus onset. As expected, the response time (RT) to the visual stimulus was slower on trials in which the TMS pulse was applied compared to trials without TMS. But surprisingly, the RT to the auditory stimulus was faster after TMS over the visual cortex. Why might disruption of the visual cortex improve a person’s ability to detect a sound? One possibility is that the two sensory systems are in competition with one another. Thus, TMS of the visual cortex handicaps

Multimodal Perception: I See WhatYou’re Sayin’ | 211 a competitor of auditory cortex. Alternatively, neurons in visual cortex that are activated by the TMS pulse might produce signals that are sent to auditory cortex (as part of a multisensory processing pathway), and in this way enhance auditory cortex activity and produce faster RTs to the sounds (Figure 5.47). Romei came up with a clever way to evaluate these two hypotheses by looking at the reverse situation, asking if an auditory stimulus could enhance visual perception. When TMS is applied over visual cortex, people report seeing phosphenes—an illusory flash of light. Phosphenes can also be produced mechanically by rubbing the eye. (The next time you go to the Louvre in Paris and stand in front of the huge epic painting of the Raft of the Medusa by Géricault, you can wow your neuroscientist friends with this bit of trivia: The word phosphene was coined by J. B. H. Savigny, the ship surgeon of the Méduse.) Romei first determined the intensity level of TMS required to produce phosphenes for each person. He then randomly stimulated the participants at a level that was a bit below the threshold in one of two conditions: alone or concurrently with an auditory stimulus. At this subthreshold level, the participants perceived phosphenes when the auditory stimulus was present, but not when the TMS pulse was presented alone. This finding supports the hypothesis that auditory and visual stimuli can enhance perception in the other sensory modality.

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What are the Pathways? All the hubbub about multisensory processing has spawned several hypotheses about the pathways and connections between the processing areas and the resulting way that the processing occurs. The most radical suggestion is that the entire neocortex is in some sense multisensory, and the initial integration has occurred subcortically (Figure 5.48a). We do know from neuroanatomy that there is multisensory input to the cortex from the thalamus, but it would be an exaggeration to think that the entire cortex is multisensory. A lesion of primary visual cortex produces a profound and permanent blindness with no real effect on the other senses (or, if anything, some enhanced sensitivity in the other senses). The primary sensory cortical regions, and even secondary sensory regions, are clearly dedicated to a single modality. A less radical version is that the cortex has specific sensory areas, but they contain some multisensory interneurons (Figure 5.48b). Alternatively, multisensory integration may involve projections originating in modality-specific cortical areas. These projections could go from one sensory region to another, allowing for fast modulation within primary and secondary sensory regions (Figure 5.48c). Or, the projections could be to multisensory convergence zones in the cortex, which in more traditional models of sensory function were referred to as association sensory areas. In these models, cross-modal influences on early sensory signals occur via feedback connections from the convergence zones to sensory-specific areas of the cortex (Figure 5.48d). All of these ideas likely contain some degree of truth. As we have pointed out repeatedly, the sensory systems of the brain have evolved to reconstruct the external environment. This process is surely facilitated by exploiting all of the available information.

TAKE-HOME MESSAGES ■

–10 RT to auditory stimulus is faster when visual cortex is disrupted.

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FIGURE 5.47 Interactions of visual and auditory information. RT to auditory stimulus is faster when visual cortex is disrupted. Participants responded as quickly as possible to a visual (V) or auditory (A) stimulus. A single TMS pulse was applied over the occipital lobe at varying delays after stimulus onset (x-axis). The yaxis shows the change in RT for the different conditions. RTs to the visual stimulus were slower (positive numbers) in the shaded area, presumably because the TMS pulse made it harder to perceive the stimulus. Interestingly, RTs to auditory stimuli were faster (negative numbers) during this same epoch.

Some areas of the brain, such as the superior colliculus and superior temporal sulci, process information from more than one sensory modality, integrating the multimodal information to increase the sensitivity and accuracy of perception. When multisensory information is presented coincidently in time and space, the multisensory neural response is enhanced. The reverse is also true; when multisensory information is not presented coincidently in time and space, the multisensory neural response is depressed.

Errors in Multimodal Processing: Synesthesia J.W. experiences the world differently from most people. He tastes words. The word exactly, for example,

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have a genetic basis (BaronCohen et al., 1996; Smilek et al., 2005). If you think that you may experience some form of synesthesia, you can find out MS by taking the tests at this webVC AC site: http://synesthete.org/. Colored-grapheme synesthesia, in which black or white letters or digits are perceived Audiovisual in assorted colors, is the beststudied form of synesthesia. A synesthete might report “seed c ing” the letter A as red, the TC TC letter B as yellow, and so forth PP for the entire set of characters, as in the example shown in AC AC STS Figure 5.49. The appearance of color is a feature of many VC VC forms of synesthesia. In colored hearing, colors are experienced for spoken words or for sounds like musical notes. Colored touch and colored smell Visual Audiovisual Multisensory (A-V-T) have also been reported. Much Auditory Audiotactile Visuotactile less common are synesthetic Tactile experiences that involve other FIGURE 5.48 Various schemes of multisensory interaction. senses. J.W. experiences taste (a) Multisensory integration occurs subcortically (e.g., thalamus). Input to cortical areas is already with words; other rare cases influenced by information from other sensory modalities. (b) Modality specific regions are surroundhave been reported in which ed by multisensory regions that receive input from other modalities. (c) Multisensory interactions touching an object induces occur through communication between modality specific regions. (d) Certain cortical areas are spespecific tastes. cialized for multisensory processing. PP = posterior parietal cortex; STS = superior temporal sulcus. The associations are idiosyncratic for each synesthete. One person might see the letter B as red, another as green. Although the synesthetic tastes like yogurt, and the word accept tastes like eggs. associations are not consistent across individuals, they Most conversations are pleasant tasting; but when J.W. are consistent over time for an individual. A synesthete is tending bar, he cringes whenever Derek, a frequent who reports the letter B as red when tested the first time customer, shows up. For J.W., the word Derek tastes of in the lab will have the same percept if retested a few earwax! months later. This phenomenon, in which the senses are mixed, is Given that synesthesia is such a personal experience, known as synesthesia, from the Greek syn– (“union” researchers have had to come up with clever methods to or “together”) and aesthesis (“sensation”). Synesthesia is characterized by an idiosyncratic union between (or within) sensory modalities. Tasting words is an extremely rare form of synesthesia. More common are synesthesias in which people hear words or music as colors, or see achromatic lettering (as in books or newspapers) as colored. The frequency of synesthesia is hard to know, given that many individuals are unaware that their multisensory percepts are odd: Estimates range from as rare as one in 2,000 to as high as one in 200. Synesthesia tends FIGURE 5.49 Artistic rendition of the color–letter and color– number associations for one individual with synesthesia. to recur in families, indicating that at least some forms a

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ABCDEFGHIJKLMNOP QRSTUVWXYZ 1234567890

Perceptual Reorganization | 213 verify and explore this unique phenomenon. One approach with colored-grapheme synesthesia is to create modified versions of the Stroop task. As described in Chapter 3 (page 78), the Stroop task requires a person to name the color of written words. For instance, if the word green is written in red ink, the subject is supposed to say “red.” In the synesthetic variant of the Stroop task with a coloredgrapheme synesthete, the stimuli are letters, and the key manipulation is whether the colors of the letters are congruent or incongruent to the individual’s synesthetic palette. For the example in Figure 5.49, when the letter A is presented in red, the physical color and synesthetic color are congruent. However, if the A is presented in green, the physical and concurrent colors are incongruent. Synesthetes are faster to name the colors of the letters when the physical color matches the concurrent colors for the particular letter (Mattingley et al., 2001). People without synesthesia, of course, do not show this effect. To them, any color–letter pairing is equally acceptable. Brain-imaging studies indicate that the multisensory experience of synesthesia arises and is manifest at various stages along the visual pathway. Jeffrey Gray at King’s College in London performed an fMRI study with a group of individuals who had colored-hearing synesthesia (Nunn et al., 2002). When listening to words, these individuals reported seeing specific colors; when listening to tones, they had no visual experience. Compared to control participants, the synesthetes showed increased activation in V4, similar to what we have seen in other studies of illusory color perception, and in the STS, one of the brain regions associated with multimodal perception. Other studies have shown recruitment of the left medial lingual gyrus (a higher-order color processing area previously implicated in color knowledge) in synesthetes during the perception of colored-grapheme synesthesia (Rich et al., 2006). A different approach is to ask if synesthesia is the result of abnormal anatomical connections. For example, do synesthetes have more connectivity between sensory regions than non-synesthetes? Using diffusion tensor imaging (DTI), Steven Scholte (2007) and his colleagues at the University of Amsterdam showed that grapheme– color synesthetes had greater anisotropic diffusion, a marker of larger white matter tracts, in the right inferior temporal cortex, the left parietal cortex, and bilaterally in the frontal cortex (green lines in Figure 5.50). Moreover, the researchers found that individual differences in the amount of connectivity in the inferior temporal cortex differentiated between subtypes of synesthetes. Participants who saw color in the outside world (known as “projectors”) had greater connectivity in the inferior temporal cortex compared with those who saw color in their “mind’s eye” only (known as “associators”).

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FIGURE 5.50 Stronger white matter connectivity in synesthetes. Green indicates white matter tracts identified with DTI in all participants. Yellow region in right inferior temporal cortex (a) and left parietal (b) show areas where the FA value is higher in synesthetes compared to controls.

TAKE-HOME MESSAGES ■

People with synesthesia experience a mixing of the senses, for example, colored hearing, colored graphemes, or colored taste. Synthesia is associated with both abnormal activation patterns in functional imaging studies and abnormal patterns of connectivity in structural imaging studies.

Perceptual Reorganization As we have just seen, people with synesthesia provide a dramatic example of how the brain is able to link information between distinct sensory systems. The extent of the connectivity between sensory systems is also revealed by studies on people who are deprived of input from one of their senses. When a person is blind, what happens to those regions of the brain that are usually used for visual perception? Might this unused neural tissue be able to reorganize to process other information, as it does on the somatosensory cortex (see Figure 5.16)? Is the situation for individuals who have been blind since birth different from that of individuals who became blind after having had vision?

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The results of one PET study suggest that a remarkable degree of functional reorganization goes on (Sadato et al., 1996). The participants in this study included people with normal vision and people who were congenitally blind—that is, blind from birth. The participants were scanned under two experimental conditions. In one condition, they were simply required to sweep their fingers back and forth over a rough surface covered with dots. In the second condition, they were given tactile discrimination tasks such as deciding whether two grooves in the surface were the same or different. Blood flow in the visual cortex during each of these tasks was compared to that during a rest condition in which the participants were scanned while keeping their hands still. Amazingly, changes in activation in the visual cortex were in opposite directions for the two groups. For the sighted participants, a significant drop in activation was found in the primary visual cortex during the tactile

discrimination tasks. Analogous decreases in the auditory or somatosensory cortex occurred during visual tasks. Therefore, as attention was directed to one modality, activation (as measured by blood flow) decreased in other sensory systems. In blind participants, however, the activation in the primary visual cortex increased during discrimination tasks, but only when they were actively using the tactile information. Interestingly, a second group of participants, who had become blind early in childhood (before their fifth year), also showed the same recruitment of visual cortex when performing the tactile discrimination task. A second experiment explored the same issue but used a task that is of great practical value to the blind: reading Braille (Sadato et al., 1998). Here, the participants explored strings of eight Braille letters and had to decide whether the strings formed a word. In accord with the results of the first study, activation of the primary and secondary visual cortex increased during Braille reading

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FIGURE 5.51 Perceptual and neural changes resulting from extended visual deprivation in sighted individuals. (a) fMRI activation during tactile exploration. By Day 5, the blindfolded group showed greater activation than the controls in the occipital cortex. This effect disappeared after the blindfold was removed. (b) Performance on tactile acuity after one or five days of practice. Lower values correspond to greater sensitivity. (Green: blindfolded participants; Red: Controls.) (c) Difference in occipital activation between blindfolded and control participants across days.

Day 6 (blindfold off)

Perceptual Reorganization | 215 in comparison with the resting state, but only in the blind participants. Of course the term visual cortex is a misnomer when applied to blind individuals. The results of the studies just described indicate that tissue, which during normal development will become sensitive to visual inputs, can be exploited in a radically different manner when the environmental context is changed—for example, when all visual input is lost. Currently, it is unclear how tactile information ends up activating neurons in the visual cortex of blind people. One possibility is that somatosensory projections to thalamic relays spread into the nearby lateral geniculate nucleus, exploiting the geniculostriate pathway. This hypothesis is unlikely, since the activation changes in the blind participants’ visual cortices were bilateral. Somatosensory inputs to the thalamus are strictly lateralized. Because they performed the tactile tasks with the right hand, the blood-flow changes should have been restricted to the left hemisphere. A more viable hypothesis is that a massive reorganization of corticocortical connections follows peripheral blindness. The sensorydeprived visual cortex is taken over, perhaps through back-projections originating in polymodal association cortical areas. Alvaro Pascual-Leone and his colleagues at Harvard Medical School (Merabet et al., 2008) have studied cortical plasticity effects that occur when sighted volunteers are deprived of visual information for an extended period. These participants were blindfolded for 5 days and received intensive Braille training (Figure 5.51). A matched control group was given the same training, but they were not blindfolded. At the end of training, the blindfolded participants could discriminate Braille letters better than the nonblindfolded participants did; those who wore blindfolds were also better at other tactile discrimination tasks. Furthermore, fMRI tests of these participants revealed activation in the visual cortex during tactile stimulation of the right or left fingertips, even with

stimuli that would not be expected to generate visual images. Interestingly, just 20 hours after the blindfold was removed (on day 6), the activation in visual cortex during tactile stimulation disappeared (Figure 5.51a, c). These data argue that, when deprived of normal input, the adult visual system rapidly reorganizes to become more proficient in processing information from the other senses. Although these studies are a dramatic demonstration of cortical plasticity, the results also suggest a neurobiological mechanism for the greater nonvisual perceptual acuity exhibited by blind people. Indeed, Louis Braille’s motivation to develop his tactile reading system was spurred by his belief that vision loss was offset by heightened sensitivity in the fingertips. One account of this compensation focuses on nonperceptual mechanisms. Though the sensory representation of somatosensory information is similar for blind and sighted participants, the former group is not distracted by vision (or visual imagery). If the focus of attention is narrowed, somatosensory information can be used more efficiently. The imaging results reviewed here, though, suggest a more perceptual account: Sensitivity increases because more cortical tissue is devoted to representing nonvisual information.

TAKE-HOME MESSAGES ■

Following sensory deprivation, the function of sensory regions of the cortex may become reorganized, or exhibit what is called plasticity. For instance, in blind individuals, areas of the brain that are usually involved in visual function may become part of the somatosensory cortex. Plasticity can also be observed in healthy individuals if they are deprived of information from one sensory modality for even relatively short periods of time.

Summary The five basic sensory systems of audition, olfaction, gustation, somatosensation, and vision allow us to interpret the environment. Each sense involves unique pathways and processes to translate external stimuli into neural signals that are interpreted by the brain. Within each sense, specialized sensory mechanisms have evolved to solve computational problems to facilitate and enhance our perceptual capabilities. As shown in neuroimaging and neuropsychological studies, specialization is found across the sensory cortices

of the brain; thus, people may retain the ability to see, even in the absence of cortical mechanisms for color or motion perception. In extreme situations of sensory deprivation, the cortical systems for perception may become radically reorganized. Even in people with intact sensory systems, the five senses do not work in isolation, but rather work in concert to construct a rich interpretation of the world. It is this integration that underlies much of human cognition and allows us to survive, and indeed thrive, in a multisensory world.

Key Terms achromatopsia (p. 201) akinetopsia (p. 204) area MT (p. 190) area V4 (p. 194) chemical senses (p. 176) corpuscle (p. 179) cortical visual area (p. 189) extrastriate visual area (p. 189) fovea (p. 186) ganglion cells (p. 186) glomerulus (p.173) hemianopia (p. 206) inferior colliculus (p. 169)

interaural time (p. 171) lateral geniculate nucleus (LGN) (p. 187) medial geniculate nucleus (MGN) (p. 167) multisensory integration (p. 167) nociceptor (p. 179) odorant (p. 173) photoreceptor (p. 185) primary auditory cortex (A1) (p. 169) primary gustatory cortex (p. 176) primary olfactory cortex (p. 173)

primary somatosensory cortex (S1) (p. 180) primary visual cortex (V1) (p. 187) proprioception (p. 180) receptive field (p. 187) retina (p. 185) retinotopic map (p. 187) scotoma (p. 206) secondary somatosensory cortex (S2) (p. 180) superior colliculus (p. 187) synesthesia (p. 212) tastant (p. 176)

Thought Questions 1.

Compare and contrast the functional organization of the visual and auditory systems. What computational problems must each system solve, and how are these solutions achieved in the nervous system?

2.

A person arrives at the hospital in a confused state and appears to have some impairment in visual perception. As the attending neurologist, you suspect that the person has had a stroke. How would you go about examining the patient to determine at which level in the visual pathways the damage has occurred? Emphasize the behavioral tests you would administer, but feel free to make predictions about what you expect to see on MRI scans.

3.

Define the physiological concepts of receptive field and visual area. How is the receptive field of a cell

216

established? How are the boundaries between visual areas identified by researchers using either single-cell recording methods or fMRI?

4.

This chapter has focused mainly on salient visual properties such as color, shape, and motion. In looking around the environment, do you think these properties seem to reflect the most important cues for a highly skilled visual creature? What other sources of information might an adaptive visual system exploit?

5.

How might abnormalities in multisensory processing (e.g., synesthesia) be important for understanding how and why information becomes integrated across different sensory channels? Similarly, given the plasticity of the brain, does it even make sense to talk about a “visual system” or an “auditory system”?

Suggested Reading Chalupa, L. M., & Warner, J. S. (Eds.). (2004). The visual neurosciences. Cambridge, MA: MIT Press.

Larsson, J., & Heeger, D. J. (2006). Two retinotopic visual areas in human lateral occipital cortex. Journal of Neuroscience, 26, 13128–13142.

Driver, J., & Noesselt, T. 2008. Multisensory interplay reveals crossmodal influences on “spensory-specific” brain regions, neural responses, and judgments. Neuron, 57, 11–23.

Palmer, S. E. (1999). Vision science: Photons to phenomenology. Cambridge, MA: MIT Press. Ward J. 2013. Synesthesia. Annual Review of Psychology, 64, 49–75.

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I never forget a face, but in your case I’ll be glad to make an exception. Groucho Mar x

chapter

Object Recognition

6

WHILE STILL IN HIS THIRTIES, patient G.S. suffered a stroke and nearly died. Although he eventually recovered most of his cognitive functions, G.S. continued to complain about one severe problem: He could not recognize objects. G.S.’s sensory abilities were intact, his language function was normal, and he had no problems with coordination. Most striking, he had no loss of OUTLINE visual acuity. He could easily judge which of two lines was longer, and he could describe the color and general shape of objects. Nonetheless, when Principles of Object Recognition shown household objects such as a candle or a salad bowl, he was unable Multiple Pathways for Visual to name them, even though he could describe the candle as long and thin, Perception and the salad bowl as curved and brown. G.S.’s deficit, however, did not reflect an inability to retrieve verbal labels of objects. When asked to name Computational Problems in Object a round, wooden object in which lettuce, tomatoes, and cucumbers are Recognition mixed, he responded “salad bowl.” He also could identify objects by using Failures in Object Recognition: other senses, such as touch or smell. For example, after visually examinThe Big Picture ing a candle, he reported that it was a “long object.” Upon touching it, he labeled it a “crayon”; but after smelling it, he corrected himself and Category Specificity in Agnosia: responded “candle.” Thus, his deficit was modality specific, confined to The Devil Is in the Details his visual system. Processing Faces: Are Faces Special? G.S. had even more difficulty recognizing objects in photographs. When shown a picture of a combination lock and asked to name the obMind Reading ject, he failed to respond at first. Then he noted the round shape. Interestingly, while viewing the picture, he kept twirling his fingers, pantomiming the actions of opening a combination lock. When asked about this, he reported that it was a nervous habit. Prompted by experimenters to provide more details or to make a guess, G.S. said that the picture was of a telephone (the patient was referring to a rotary dial telephone, which was commonly used in his day). He remained adamant about this guess, even after he was informed that it was not a picture of a telephone. Finally, the experimenter asked him if the object in the picture was a telephone, a lock, or a clock. By this time, convinced it was not a telephone, he responded “clock.” Then, after a look at his fingers, he proudly announced, “It’s a lock, a combination lock.” 219

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G.S.’s actions were telling. Even though his eyes and optic nerve functioned normally, he could not recognize an object that he was looking at. In other words, sensory information was entering his visual system normally, and information about the components of an object in his visual field was being processed. He could differentiate and identify colors, lines, and shapes. He knew the names of objects and what they were for, so his memory was fine. Also, when viewing the image of a lock, G.S.’s choice of a telephone was not random. He had perceived the numeric markings around the lock’s circumference, a feature found on rotary dial telephones. G.S.’s finger twirling indicated that he knew more about the object in the picture than his erroneous statement that it was a telephone. In the end, his hand motion gave him the answer. G.S. had let his fingers do the talking. Although his visual system perceived the parts, and he understood the function of the object he was looking at, G.S. could not put all of that information together to recognize the object. G.S. had a type of visual agnosia.

Principles of Object Recognition Failures of visual perception can happen even when the processes that analyze color, shape, and motion are intact. Similarly, a person can have a deficit in her auditory, olfactory, or somatosensory system even when her sense of hearing, smell, or touch is functioning normally. Such disorders are referred to as agnosias. The label was coined by Sigmund Freud, who derived it from the Greek a– (“without”) and gnosis (“knowledge”). To be agnosic means to experience a failure of knowledge, or recognition. When the disorder is limited to the visual modality, as with G.S., the syndrome is referred to as visual agnosia. Patients with visual agnosia have provided a window into the processes that underlie object recognition. As we discover in this chapter, by analyzing the subtypes of visual agnosia and their associated deficits, we can draw inferences about the processes that lead to object recognition. Those inferences can help cognitive neuroscientists develop detailed models of these processes. As with many neuropsychological labels, the term visual agnosia has been applied to a number of distinct disorders associated with different neural deficits. In some patients, the problem is one of developing a coherent percept—the basic components are there, but they can’t be assembled. It’s somewhat like going to Legoland and—instead of seeing the integrated per-

cepts of buildings, cars, and monsters—seeing nothing but piles of Legos. In other patients, the components are assembled into a meaningful percept, but the object is recognizable only when observed from a certain angle—say from the side, but not from the front. In other instances, the components are assembled into a meaningful percept, but the patient is unable to link that percept to memories about the function or properties of the object. When viewing a car, the patient might be able to draw a picture of that car, but is still unable to tell that it is a car or describe what a car is for. Patient G.S.’s problem seems to be of this last form. Despite his relatively uniform difficulty in identifying visually presented objects, other aspects of his performance— in particular, the twirling fingers—indicate that he has retained knowledge of this object, but access to that information is insufficient to allow him to come up with the name of the object. When thinking about object recognition, there are four major concepts to keep in mind. First, at a fundamental level, the case of patient G.S. forces researchers to be precise when using terms like perceive or recognize. G.S. can see the pictures, yet he fails to perceive or recognize them. Distinctions like these constitute a core issue in cognitive neuroscience, highlighting the limitations of the language used in everyday descriptions of thinking. Such distinctions are relevant in this chapter, and they will reappear when we turn to problems of attention and memory in Chapters 7 and 9. Second, as we saw in Chapter 5, although our sensory systems use a divide-and-conquer strategy, our perception is of unified objects. Features like color and motion are processed along distinct neural pathways. Perception, however, requires more than simply perceiving the features of objects. For instance, when gazing at the northern coastline of San Francisco (Figure 6.1), we do not see just blurs of color floating among a sea of various shapes. Instead, our percepts are of the deep-blue water of the bay, the peaked towers of the Golden Gate Bridge, and the silver skyscrapers of the city. Third, perceptual capabilities are enormously flexible and robust. The city vista looks the same whether people view it with both eyes or with only the left or the right eye. Changing our position may reveal Golden Gate Park in the distance or it may present a view in which a building occludes half of the city. Even so, we readily recognize that we are looking at the same city. The percept remains stable even if we stand on our head and the retinal image is inverted. We readily attribute the change in the percept to our viewing position. We do not see the world as upside down. We could move across the bay and gaze at the city from a

Principles of Object Recognition | 221

a

b FIGURE 6.1 Our view of the world depends on our vantage point. These two photographs are taken of the same scene, but from two different positions and under two different conditions. Each vantage point reveals new views of the scene, including objects that were obscured from the other vantage point. Moreover, the colors change, depending on the time of day and weather. Despite this variability, we easily recognize that both photographs are of the Golden Gate Bridge, with San Francisco in the distance.

different angle and still recognize it. Somehow, no matter if the inputs are partial, upside down, full face, or sideways, hitting varying amounts of the retina or all of it, the brain interprets it all as the same object and identifies it: “That, my friend, is San Francisco!” We take this constancy for granted, but it is truly amazing when we consider how the sensory signals are radically different with each viewing position. (Curiously, this stability varies for different classes of objects. If, while upside down, we catch sight of a group of people walking toward us, then we will not recognize a friend quite as readily as when seeing her face in the normal, upright position. As we shall see, face perception has some unique properties.) Fourth, the product of perception is also intimately interwoven with memory. Object recognition is more than

linking features to form a coherent whole; that whole triggers memories. Those of us who have spent many hours roaming the hills around San Francisco Bay recognize that the pictures in Figure 6.1 were taken from the Marin headlands just north of the city. Even if you have never been to San Francisco, when you look at these pictures, there is interplay between perception and memory. For the traveler arriving from Australia, the first view of San Francisco is likely to evoke comparisons to Sydney; for the first-time tourist from Kansas, the vista may be so unusual that she recognizes it as such: a place unlike any other that she has seen. In the previous chapter, we saw how objects and scenes from the external world are disassembled and input into the visual system in the form of lines, shapes, and colors. In this chapter, we explore how the brain processes those low-level inputs into the high-level, coherent, memory-invoking percepts of everyday life. We begin with a discussion of the cortical real estate that is involved in object recognition. Then, we look at some of the computational problems that the object recognition system has to solve. After that, we turn to patients with object recognition deficits and consider what their deficits tell us about perception. Next, we delve into the fascinating world of category-specific recognition problems and their implications for processing. Along the way, it will be useful to keep in mind the four concepts introduced earlier: Perception and recognition are two different animals; we perceive objects as unified wholes, and do so in a manner that is highly flexible; and our perception and memory are tightly bound. We close the chapter with a look at how researchers are putting theories of object recognition to the test by trying to predict what a person is viewing simply by looking at his fMRI scans—the 21stcentury version of mind reading.

TAKE-HOME MESSAGES ■

Sensation, perception, and recognition refer to distinct phenomena.

People perceive an object as a unified whole, not as an entity separated by its color, shape, and details.

Although our visual perspective changes, our ability to recognize objects remains robust.

Memory and perception are tightly linked.

Patients with visual agnosia are unable to recognize common objects presented to them visually. This deficit is modality specific. Patients can recognize an object when they touch, smell, taste, or hear it.

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ANATOMICAL ORIENTATION

The anatomy of object recognition Occipital lobe

Posterior parietal

Occipital cortex

Superior temporal sulcus (another face region)

Fusiform gyrus Parahippocampal area

Lateral occipital and posterior inferior temporal

Anterior inferior temporal Specific regions of the brain are used for distinct types of object recognition. The parahippocampal area and posterior parietal cortex process information about places and scenes. Multiple regions are involved in face recognition, including fusiform gyrus and superior temporal sulcus, while other body parts are recognized using areas within the lateral occipital and posterior inferior temporal cortex.

Multiple Pathways for Visual Perception The pathways carrying visual information from the retina to the first few synapses in the cortex clearly segregate into multiple processing streams. Much of the information goes to the primary visual cortex (also called V1 or striate cortex; see Chapter 5 and Figures 5.23 and 5.24), located in the occipital lobe. Output from V1 is contained primarily in two major fiber bundles, or fasciculi. Figure 6.2 shows that the superior longitudinal fasciculus takes a dorsal path from the striate cortex and

Posteroparietal cortex

other visual areas, terminating mostly in the posterior regions of the parietal lobe. The inferior longitudinal fasciculus follows a ventral route from the occipital striate cortex into the temporal lobe. These two pathways are referred to as the ventral (occipitotemporal) stream and the dorsal (occipitoparietal) stream. This anatomical separation of information-carrying fibers from the visual cortex to two separate regions of the brain raises some questions. What are the different properties of processing within the ventral and dorsal streams? How do they differ in their representation of the visual input? How does processing within these two streams interact to support object perception?

Superior longitudinal fasciculus

"Where" Dorsal stream

V1

"What"

a–b

Inferior temporal cortex

Inferior longitudinal fasciculus

Ventral stream

FIGURE 6.2 The major object recognition pathways. (a) The longitudinal fasciculus, shown here in shades of purple. (b) The ventral “what” pathway terminates in the inferotemporal cortex, and the dorsal “where” pathway terminates in the posteroparietal cortex.

HOW THE BRAIN WORKS

Now You See It, Now You Don’t As his recordings moved up the ventral pathway, Logothetis found an increase in the percentage of active cells, with activity mirroring the animals’ perception rather than the stimulus conditions. In V1, the responses of less than 20% of the cells fluctuated as a function of whether the animal perceived the effective or ineffective stimulus. In V4, this percentage increased to over 33%. In contrast, the activity of all the cells in the visual areas of the temporal lobe was tightly correlated with the animal’s perception. Here the cells would respond only when the effective stimulus, the monkey face, was perceived (Figure 2). When the animal pressed the lever indicating that it perceived the ineffective stimulus (the starburst) under rivalrous conditions, the cells were essentially silent. In both V4 and the temporal lobe, the cell activity changed in advance of the animal’s response, indicating that the percept had changed. Thus, even when the stimulus did not change, an increase in activity was observed prior to the transition from a perception of the ineffective stimulus to a perception of the effective stimulus. These results suggest a competition during the early stages of cortical processing between the two possible percepts. The activity of the cells in V1 and in V4 can be thought of as perceptual hypotheses, with the patterns across an ensemble of cells reflecting the strength of the different hypotheses. Interactions between these cells ensure that, by the time the information reaches the inferotemporal lobe, one of these hypotheses has coalesced into a stable percept. Reflecting the properties of the real world, the brain is not fooled into believing that two objects exist at the same place at the same time.

Stimulus Spikes/s

Gaze at the picture in Figure 1 for a couple of minutes. If you are like most people, you initially saw a vase. But surprise! After a while the vase changed to a picture of two human profiles staring at each other. With continued viewing, your perception changes back and forth, satisfied with one interpretation until suddenly the other asserts itself and refuses to yield the floor. This is an example of multistable perception. How are multistable percepts resolved in the brain? The stimulus information does not change at the points of transition. Rather, the interpretation of the pictorial cues changes. When staring at the white region, you see the vase. If you shift attention to the black regions, you see the profiles. But here we run into a chicken-and-egg question. Did the representation of individual features change first and thus cause the percept to change? Ordid the percept change and lead to a reinterpretation of the features? To explore these questions, Nikos Logothetis of the Max Planck Institute in Tübingen, Germany, turned to a different form of multistable perception: binocular rivalry (Sheinberg & Logothetis, 1997). The exquisite focusing capability of our eyes (perhaps assisted by an optometrist) makes us forget that they provide two separate snapshots of the world. These snapshots are only slightly different, and they provide important cues for depth perception. With some technological tricks, however, it is possible to present radically different inputs to the two eyes. To accomplish this, researchers employ special glasses that have a shutter which alternately blocks the input to one eye and then the other at very rapid rates. Varying the stimulus in synchrony with the shutter allows a different stimulus to be presented to each eye. Do we see two things simultaneously at the same location? The answer is no. As with the ambiguous vase–face profiles picture, only one object or the other is seen at any single point in time, although at transitions there is sometimes a period of fuzziness in which neither object is clearly perceived. Logothetis trained his monkeys to press one of two levers to indicate which object was being perceived. To make sure the animals were not responding randomly, he included nonrivalrous trials in which only one of the objects was presented. Hethen recorded from single cells in various areas of the visual cortex. Within each area he selected two objects, only one of which was effective in driving the cell. In this way he could correlate the activity FIGURE 1 Does your perception of the cell with the animal’s change over time as you conperceptual experience. tinue to stare at this drawing?

100 50 0 Left

10 Time (s)

Right

Left

Report

15

FIGURE 2 When the starburst or monkey face is presented alone, the cell in the temporal cortex responds vigorously to the monkey face but not to the starburst. In the rivalrous condition, the two stimuli are presented simultaneously, one to the left eye and one to the right eye. The bottom bar shows the monkey’s perception, indicated by a lever press. About 1 s after the onset of the rivalrous stimulus, the animal perceives the starburst; the cell is silent during this period. About 7 s later, the cell shows a large increase in activity and, correspondingly, indicates that its perception has changed to the monkey face shortly thereafter. Then, 2 s later, the percept flips back to the starburst and the cell’s activity is again reduced.

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The What and Where Pathways To address the first of these questions, Leslie Ungerleider and Mortimer Mishkin, at the National Institutes of Health, proposed that processing along these two pathways is designed to extract fundamentally different types of information (Ungerleider & Mishkin, 1982). They hypothesized that the ventral stream is specialized for object perception and recognition—for determining what we’re looking at. The dorsal stream is specialized for spatial perception—for determining where an object is—and for analyzing the spatial configuration between different objects in a scene. “What” and “where” are the two basic questions to be answered in visual perception. To respond appropriately, we must (a) recognize what we’re looking at and (b) know where it is. The initial data for the what–where dissociation of the ventral and dorsal streams came from lesion studies with monkeys. Animals with bilateral lesions to the temporal lobe that disrupted the ventral stream had great difficulty discriminating between different shapes—a “what” discrimination (Pohl, 1973). For example, they made many errors while learning that one object, such as a cylinder, was associated with a food reward when paired with another object (e.g., a cube). Interestingly, these same animals had no trouble determining where an object was in relation to other objects; this second ability depends on a “where” computation. The opposite was true for animals with parietal lobe lesions that disrupted the dorsal stream. These animals had trouble discriminating where an object was in relation to other objects (“where”) but had no problem discriminating between two similar objects (“what”). More recent evidence indicates that the separation of what and where pathways is not limited to the visual system. Studies with various species, including humans, suggest that auditory processing regions are similarly divided. The anterior aspects of primary auditory cortex are specialized for auditory-pattern processing (what is the sound?), and posterior regions are specialized for identifying the spatial location of a sound (where is it coming from?). One particularly clever experiment demonstrated this functional specialization by asking cats to identify the where and what of an auditory stimulus (Lomber & Malhotra, 2008). The cats were trained to perform two different tasks: one task required the animal to locate a sound, and a second task required making discriminations between different sound patterns. The researchers then placed thin tubes over the anterior auditory region; through these tubes, a cold liquid could be passed to cool the underlying neural tissue. This procedure temporarily inactivates the targeted tissue, providing a transient lesion (akin to the logic of TMS studies conducted with people). Cooling resulted in selective

deficits in the pattern discrimination task, but not in the localization task. In a second phase of the study, the tubes were repositioned over the posterior auditory region. This time there was a deficit in the localization task, but not in the pattern discrimination one—a neat double dissociation in the same animal.

Representational Differences Between the Dorsal and Ventral Streams Neurons in both the temporal and parietal lobes have large receptive fields, but the physiological properties of the neurons within each lobe are quite distinct. Neurons in the parietal lobe may respond similarly to many different stimuli (Robinson et al., 1978). For example, a parietal neuron recorded in a fully conscious monkey might be activated when a stimulus such as a spot of light is restricted to a small region of space or when the stimulus is a large object that encompasses much of the hemifield. In addition, many parietal neurons are responsive to stimuli presented in the more eccentric parts of the visual field. Although 40 % of these neurons have receptive fields near the central region of vision (the fovea), the remaining cells have receptive fields that exclude the foveal region. These eccentrically tuned cells are ideally suited for detecting the presence and location of a stimulus, especially one that has just entered the field of view. Remember in Chapter 5 that, when examining subcortical visual processing, we suggested a similar role for the superior colliculus, which also plays an important role in visual attention (discussed in Chapter 7). The response of neurons in the ventral stream of the temporal lobe is quite different (Ito et al., 1995). The receptive fields for these neurons always encompass the fovea, and most of these neurons can be activated by a stimulus that falls within either the left or the right visual field. The disproportionate representation of central vision appears to be ideal for a system devoted to object recognition. We usually look directly at things we wish to identify, thereby taking advantage of the greater acuity of foveal vision. Cells within the visual areas of the temporal lobe have a diverse pattern of selectivity (Desimone, 1991). In the posterior region, earlier in processing, cells show a preference for relatively simple features such as edges. Others, farther along in the processing stream, have a preference for much more complex features such as human body parts, apples, flowers, or snakes. Recordings from one such cell, located in the inferotemporal cortex, are shown in Figure 6.3. This cell is most highly activated by the human hand. The first five images in the figure show the response of the cell to various views of a hand. Activity is high regardless of the hand’s orientation and is only slightly reduced when the hand is considerably

Multiple Pathways for Visual Perception | 225 Image presented

Neural activity

Strongest response

1

2

Perception for Identification Versus Perception for Action

3

4

Firing rate

5

6

The PET data for the two tasks were compared directly to identify neural regions that were selectively activated by one task or the other. In this way, areas that were engaged similarly for both tasks—because of similar perception, decision, or response requirements—were masked. During the position task, regional cerebral blood flow was higher in the parietal lobe in the right hemisphere (Figure 6.4b, left panel). In contrast, the object task led to increased regional cerebral blood flow bilaterally at the junction of the occipital and temporal lobes (Figure 6.4b, right panel).

Weakest response Time Stimulus presented

FIGURE 6.3 Single-cell recordings from a neuron in the inferior temporal cortex. Neurons in the inferior temporal cortex rarely respond to simple stimuli such as lines or spots of light. Rather, they respond to more complex objects such as hands. This cell responded weakly when the image did not include the defining fingers (6).

smaller. The sixth image, of a mitten, shows that the response diminishes if the same shape lacks defining fingers. Neuroimaging studies with human participants have provided further evidence that the dorsal and ventral streams are activated differentially by “where” and “what” tasks. In one elegant study using positron emission tomography (S. Kohler et al., 1995), trials consisted of pairs of displays containing three objects each (Figure 6.4a). In the position task, the participants had to determine if the objects were presented at the same locations in the two displays. In the object task, they had to determine if the objects remained the same across the two displays. The irrelevant factor could remain the same or change: The objects might change on the position task, even though the locations remained the same; similarly, the same objects might be presented at new locations in the object task. Thus, the stimulus displays were identical for the two conditions; the only difference was the task instruction.

Patient studies offer more support for a dissociation of “what” and “where” processing. As we shall see in Chapter 7, the parietal cortex is central to spatial attention. Lesions of this lobe can also produce severe disturbances in the ability to represent the world’s spatial layout and the spatial relations of objects within it. More revealing have been functional dissociations in the performance of patients with visual agnosia. Mel Goodale and David Milner (1992) at the University of Western Ontario described a 34-year-old woman, D.F., who suffered carbon monoxide intoxication because of a leaky propane gas heater. For D.F., the event caused a severe object recognition disorder. When asked to name household items, she made errors such as labeling a cup an “ashtray” or a fork a “knife.” She usually gave crude descriptions of a displayed object; for example, a screwdriver was “long, black, and thin.” Picture recognition was even more disrupted. When shown drawings of common objects, D.F. could not identify a single one. Her deficit could not be attributed to anomia, a problem with naming objects, because whenever an object was placed in her hand, she identified it. Sensory testing indicated that D.F.’s agnosia could not be attributed to a loss of visual acuity. She could detect small gray targets displayed against a black background. Although her ability to discriminate small differences in hue was abnormal, she correctly identified primary colors. Most relevant to our discussion is the dissociation of D.F.’s performance on two tasks, both designed to assess her ability to perceive the orientation of a three-dimensional object. For these tasks, D.F. was asked to view a circular block into which a slot had been cut. The orientation of the slot could be varied by rotating the block. In the explicit matching task, D.F. was given a card and asked to orient her hand so that the card would fit into the slot. D.F. failed miserably, orienting the card vertically even when the slot was horizontal (Figure 6.5a). When asked to insert the card into the slot, however, D.F. quickly reached forward and inserted the card (Figure 6.5b). Her performance on this

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that D.F. could not recognize the orientation of a threePosition retrieval minus dimensional object; this defiobject retrieval cit is indicative of her severe agnosia. Yet when D.F. was Lateral asked to insert the card (the action task), her performance clearly indicated that she had Object task processed the orientation of the slot. While shape and orientation information were not available to the processing system for objects, they Medial Object retrieval minus were available for the visuoposition retrieval motor task. This dissociation Position task suggests that the “what” and “where” systems may carry similar information, but they Lateral b each support different aspects of cognition. The “what” system is essential for determining the identity of an object. If the obFIGURE 6.4 Matching task used to contrast position and object discrimination. (a) Object and position matching to sample task. The Study and Test displays each contain three ject is familiar, people will recobjects in three positions. On object retrieval trials, the participant judges if the three objects were ognize it as such; if it is novel, the same or different. On position retrieval trials, the participant judges if the three objects are in the we may compare the percept same or different locations. In the examples depicted, the correct response would be “same” for the to stored representations of object task trial and “different” for the position task trial. (b) Views of the right hemisphere showing similarly shaped objects. The cortical regions that showed differential pattern of activation in the position and object retrieval tasks. “where” system appears to be essential for more than determining the locations of different objects; it is also critivisuomotor task did not depend on tactile feedback that cal for guiding interactions with these objects. D.F.’s perwould result when the card contacted the slot; her hand formance is an example of how information accessible was properly oriented even before she reached the block. to action systems can be dissociated from information D.F.’s performance showed that the two processaccessible to knowledge and consciousness. Indeed, ing systems make use of perceptual information from Goodale and Milner argued that the dichotomy should be different sources. The explicit matching task showed Sample stimulus

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b FIGURE 6.5 Dissociation between perception linked to awareness and perception linked to action. (a) The patient performed poorly in the explicit matching task when asked to match the orientation of the card to that of the slot. (b) In the action task, the patient was instructed to insert the card in the slot. Here, she produced the correct action without hesitation.

Multiple Pathways for Visual Perception | 227 and irregular shapes, J.S. found it very challenging to between “what” and “how,” to emphasize that the dorsal say if they were the same or different, yet could easvisual system provides a strong input to motor systems to ily modify his hand shape to pick up each object. As compute how a movement should be produced. Consider with D.F., J.S. displays a compelling dissociation in his what happens when you grab a glass of water to drink. abilities for object identification, even though his acYour visual system has factored in where the glass is in tions indicate that he has “perceived” in exquisite detail relation to your eyes, your head, the table, and the path the shape and orientation of the objects. MRIs of J.S.’s required to move the water glass directly to your mouth. brain revealed damage limited to the medial aspect of Goodale, Milner, and their colleagues have subsethe ventral occipitotemporal cortex (OTC). Note that quently tested D.F. in many studies to explore the neuJ.S.’s lesions are primarily in the medial aspect of the ral correlates of this striking dissociation between vision OTC, but D.F.’s lesions were primarily in lateral occipifor recognition and vision for action (Goodale & Milner, tal cortex. Possibly both the lateral and medial parts of 2004). Structural MRI scans showed that D.F. has widethe ventral stream are needed for object recognition, or spread cortical atrophy with concentrated bilateral lesions perhaps the diffuse pathology associated with carbon in the ventral stream that encompass lateral occipital cormonoxide poisoning in D.F. has affected function withtex (LOC) (Figure 6.6; T. James et al., 2003). Functional in the medial OTC as well. MRI scans show that D.F. does have some ventral activaPatients like D.F. and J.S. offer examples of single distion in spared tissue when she was attempting to recognize sociations. Each shows a selective (and dramatic) impairobjects, but it was more widespread than is normally seen ment in using vision to recognize objects while remaining in controls. In contrast, when asked to grasp objects, D.F. proficient in using vision to perform actions. The opposhowed robust activity in anterior regions of the inferior site dissociation can also be found in the clinical literaparietal lobe. This activity is similar to what is observed in ture: Patients with optic ataxia can recognize objects, neurologically healthy individuals (Culham et al., 2003). yet cannot use visual information to guide their actions. Patients who suffer from carbon monoxide intoxication For instance, when someone with optic ataxia reaches typically have diffuse damage, so it is difficult to pinpoint the for an object, she doesn’t move directly toward it; rather, source of the behavioral deficits. Therefore, cognitive neuroscientists tend to focus their studies on patients with more focal lesions, such as those that result from stroke. One recent case study describes a patient, J.S., with an intriguing form of visual agnosia (Karnath et al., 2009). J.S. complained that he was unable to see objects, watch TV, or read. He could dress himself, but only if he knew beforehand exactly where his clothes were located. What’s more, he was unable to recognize familiar people by their faces, even though he could identify them by their voices. Oddly enough, however, he was able to walk around the neighborhood without a problem. He could easily grab objects presented to him at different locations, even though he could not identify the objects. J.S. was examined using tests similar to those used in the studies with D.F. (see Figure 6.5). When shown an object, he performed poorly in describing its size; but FIGURE 6.6 Ventral-stream lesions in patient D.F. shown in comparison with the functionally-defined lateral occipital complex (LOC) in healthy participants. he could readily pick it up, adjust- (a) Reconstruction of D.F.’s brain lesion. Lateral views of the left and right hemispheres are shown, ing his grip size to match the ob- as is a ventral view of the underside of the brain. (b) The highlighted regions indicate activation in ject’s size. Or, if shown two flat the lateral occipital cortex of neurologically healthy individuals when they are recognizing objects.

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she gropes about like a person trying to find a light switch in the dark. Although D.F. had no problem avoiding obstacles when reaching for an object, patients with optic ataxia fail to take obstacles into account as they reach for something (Schindler et al., 2004). Their eye movements present a similar loss of spatial knowledge. Saccades, or directed eye movements, may be directed inappropriately and fail to bring the object within the fovea. When tested on the slot task used with D.F. (see Figure 6.5), these patients can report the orientation of a visual slot, even though they cannot use this information when inserting an object in the slot. In accord with what researchers expect on the basis of dorsal–ventral dichotomy, optic ataxia is associated with lesions of the parietal cortex. Although these examples are dramatic demonstrations of functional separation of “what” and “where” processing, do not forget that this evidence comes from the study of patients with rare disorders. It is also important to see if similar principles hold in healthy brains. Lior Shmuelof and Ehud Zohary designed a study to compare activity patterns in the dorsal and ventral streams in normal subjects (Shmuelof & Zohary, 2005). The participants viewed video clips of various objects that were being manipulated by a hand. The objects were presented in either the left or right visual field, and the hand approached the object from the opposite visual field (Figure 6.7a). Activation of the dorsal parietal region was driven by the position of the hand (Figure 6.7b). For example, when viewing a right hand reaching for an object in the left visual field, the activation was stronger in the left parietal region. In contrast, activation in ventral occipitotemporal cortex was correlated with the position of the object. In a second experiment, the participants were asked either to identify the object or judge how many fingers were used to grasp the object. Here again, ventral activation was stronger for the object identification task, but dorsal activation was stronger for the finger judgment task (Figure 6.7c). In sum, the what–where or what–how dichotomy offers a functional account of two computational goals of higher visual processing. This distinction is best viewed as heuristic rather than absolute. The dorsal and ventral streams are not isolated from one another, but rather communicate extensively. Processing within the parietal lobe, the termination of the “where” pathway, serves many purposes. We have focused here on its guiding of action; in Chapter 7 we will see that the parietal lobe also plays a critical role in selective attention, the enhancement of processing at some locations instead of others. Moreover, spatial information can be useful for solving “what” problems. For example,

depth cues help segregate a complex scene into its component objects. The rest of this chapter concentrates on object recognition—in particular, the visual system’s assortment of strategies that make use of both dorsal and ventral stream processing for perceiving and recognizing the world.

TAKE-HOME MESSAGES ■

The ventral stream, or occipitotemporal pathway, is specialized for object perception and recognition. Thisis often referred to as the “what” pathway. It focuses on “vision for recognition.”

The dorsal stream, or occipitoparietal pathway, is specialized for spatial perception and is often referred toas the “where” or “how” pathway. It focuses on “vision for action.”

Neurons in the parietal lobe have large, nonselective receptive fields that include cells representing both the fovea and the periphery. Neurons in the temporal lobe have large receptive fields that are much more selective and always represent foveal information.

Patients with selective lesions of the ventral pathway may have severe problems in consciously identifying objects, yet they can use the visual information to guide coordinated movement. Thus we see that visual information is used for a variety of purposes.

Patients with optic ataxia can recognize objects but cannot use visual information to guide action. Optic ataxia is associated with lesions of the parietal cortex.

Computational Problems in Object Recognition Object perception depends primarily on an analysis of the shape of a visual stimulus. Cues such as color, texture, and motion certainly also contribute to normal perception. For example, when people look at the surf breaking on the shore, their acuity is not sufficient to see grains of sand, and water is essentially amorphous, lacking any definable shape. Yet the textures of the sand’s surface and the water’s edge, and their differences in color, enable us to distinguish between the two regions. The water’s motion is important too. Nevertheless, even if surface features like texture and color are absent or applied inappropriately, recognition is minimally affected: We can readily identify an elephant, an apple, and the human form in Figure 6.8, even though they are shown as pink, plaid, and wooden, respectively. Here object recognition is derived from a perceptual ability to match an analysis of shape and form to an object, regardless of color, texture, or motion cues.

Computational Problems in Object Recognition | 229 Left hand/Right object “How many fingers?”

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FIGURE 6.7 Hemispheric asymmetries depend on location of object and hand used to reach the object. (a) Video clips showed a left or right hand, being used to reach for an object on the left or right side of space. In the “Action” condition, participants judged the number of fingers used to contact the object. In the “Recognition” condition, participants named the object. (b) Laterality pattern in dorsal and ventral regions reveal preference for either the hand or object. Dorsal activation is related to the position of the hand, being greater in the hemisphere contralateral to the hand grasping the object. Ventral activation is related to the position of the object, being greater in the hemisphere contralateral to the object being grasped. (c) Combining across right hand and left hand pictures, dorsal activation in the intraparietal sulcus (orange) was stronger when judging how many fingers would be required to grasp the object, whereas ventral activation in occipitotemporal cortex (blue) was greater when naming the object.

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FIGURE 6.8 Analyzing shape and form. Despite the irregularities in how these objects are depicted, most people have little problem recognizing them. We may never have seen pink elephants or plaid apples, but our object recognition system can still discern the essential features that identify these objects as elephants and apples.

To account for shape-based recognition, we need to consider two problems. The first has to do with shape encoding. How is a shape represented internally? What enables us to recognize differences between a triangle and a square or between a chimp and a person? The second problem centers on how shape is processed, given that the position from which an object is viewed varies. We recognize shapes from an infinite array of positions and orientations, and our recognition system is not hampered by scale changes in the retinal image as we move close to or away from an object. Let’s start with the latter problem.

Moreover, while the visible parts of an object may differ depending on how light hits it and where shadows are cast (Figure 6.9b), recognition is largely insensitive to changes in illumination. A dog in the sun and dog in the shade still register as a dog.

Variability in Sensory Information Object constancy refers to our amazing ability to recognize an object in countless situations. Figure 6.9a shows four drawings of an automobile that have little in common with respect to sensory information reaching the eye. Yet we have no problem identifying the object in each picture as a car, and discerning that all four cars are the same model. The visual information emanating from an object varies for several reasons: viewing position, how it is illuminated, and the object’s surroundings. First, sensory information depends highly on viewing position. Viewpoint changes not only as you view an object from different angles, but when the object itself moves and thus changes its orientation relative to you. When a dog rolls over, or you walk around the room gazing at him, your interpretation of the object (the dog) remains the same despite the changes in how the image hits the retina and the retinal projection of shape. The human perceptual system is adept at separating changes caused by shifts in viewpoint from changes intrinsic to an object itself.

a

b FIGURE 6.9 Object constancy. (a) The image on the retina is vastly different for these four drawings of a car. (b) Other sources of variation in the sensory input include shadows and occlusion (where one object is in front of another). Despite this sensory variability, we rapidly recognize the objects and can judge if they depict the same object or different objects.

Computational Problems in Object Recognition | 231 Lastly, objects are rarely seen in isolation. People see objects surrounded by other objects and against varied backgrounds. Yet, we have no trouble separating a dog from other objects on a crowded city street, even when the dog is partially obstructed by pedestrians, trees, and hydrants. Our perceptual system quickly partitions the scene into components. Object recognition must overcome these three sources of variability. But it also has to recognize that changes in perceived shape can actually reflect changes in the object. Object recognition must be general enough to support object constancy, and it must also be specific enough to pick out slight differences between members of a category or class.

View-Dependent Versus View-Invariant Recognition A central debate in object recognition has to do with defining the frame of reference in which recognition occurs (D. Perrett et al., 1994). For example, when we look at a bicycle, we easily recognize it from its most typical view, from the side; but we also recognize it when looking down upon it or straight on. Somehow, we can take two-dimensional information from the retina and recognize a three-dimensional object from any angle. Various theories have been proposed to explain how we solve the problem of viewing position. These theories can be grouped into two categories: recognition is dependent on the frame of reference; or, recognition is independent of the frame of reference. Theories with a view-dependent frame of reference posit that people have a cornucopia of specific representations in memory; we simply need to match a stimulus to a stored representation. The key idea is that the stored representation for recognizing a bicycle from the side is different from the one for recognizing a bicycle viewed from above (Figure 6.10). Hence, our ability to recognize that two stimuli are depicting the same object is assumed to arise at a later stage of processing. One shortcoming with view-dependent theories is that they seem to place a heavy burden on perceptual memory. Each object requires multiple representations in memory, each associated with a different vantage point. This problem is less daunting, however, if we assume that recognition processes are able to match the input to stored representations through an interpolation process. We recognize an object seen from a novel viewpoint by comparing the stimulus information to the stored representations and choosing the best match. When our viewing position of a bicycle is at a 41° angle, relative to vertical, a stored representation of a bicycle viewed at 45° is likely good enough to allow us to recognize the

FIGURE 6.10 View-dependent object recognition. View-dependent theories of object recognition posit that recognition processes depend on the vantage point. Recognizing that all four of these drawings depict a bicycle—one from a side view, one from an aerial view, and two viewed at an angle—requires matching the distinct sensory inputs to view-dependent representations.

object. This idea is supported by experiments using novel objects—an approach that minimizes the contribution of the participants’ experience and the possibility of verbal strategies. The time needed to decide if two objects are the same or different increases as the viewpoints diverge, even when each member of the object set contains a unique feature (Tarr et al., 1997). An alternative scheme proposes that recognition occurs in a view-invariant frame of reference. Recognition does not happen by simple analysis of the stimulus information. Rather, the perceptual system extracts structural information about the components of an object and the relationship between these components. In this scheme, the key to successful recognition is that critical properties remain independent of viewpoint (Marr, 1982). To stay with the bicycle example, the properties might be features such as an elongated shape running along the long axis, combined with a shorter, stick-like shape coming off of one end. Throw in two circularshaped parts, and we could recognize the object as a bicycle from just about any position. As the saying goes, there’s more than one way to skin a cat. In fact, the brain may use both view-dependent and view-invariant operations to support object recognition. Patrick Vuilleumier and his colleagues at University College London explored this hypothesis in an fMRI study (Vuilleumier et al., 2002). The study was motivated by the finding from various imaging studies that, when a stimulus is repeated, the blood oxygen level– dependent (BOLD) response is lower in the second presentation compared to the first. This repetition suppression effect is hypothesized to indicate increased neural

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efficiency: The neural response to the stimulus is more efficient and perhaps faster when the pattern has been recently activated. To ask about view dependency, study participants were shown pictures of objects, and each picture was repeated over the course of the scanning session. The second presentation was either in the same orientation or from a different viewpoint. Experimenters observed a repetition suppression effect in left ventral occipital cortex, regardless of whether the object was shown from the same or a different viewpoint (Figure 6.11a), consistent with a view-invariant representation. In contrast, activation in right ventral occipital cortex decreased only when the second presentation was from the original viewpoint (Figure 6.11b), consistent with a view-dependent representation. When the object was shown from a new viewpoint, the BOLD response was similar to that observed for the object in the initial presentation. Thus the two hemispheres may process information in different ways, providing two snapshots of the world (this idea is discussed in more detail in Chapter 4).

Shape Encoding Now let’s consider how shape is encoded. In the last chapter, we introduced the idea that recognition may involve hierarchical representations in which each successive stage adds complexity. Simple features such as lines

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can be combined into edges, corners, and intersections, which—as processing continues up the hierarchy—are grouped into parts, and the parts grouped into objects. People recognize a pentagon because it contains five line segments of equal length, joined together to form five corners that define an enclosed region (Figure 6.12). The same five line segments can define other objects, such as a pyramid. With the pyramid, however, there are only four points of intersection, not five; and the lines define a more complicated shape that implies it is three-dimensional. The pentagon and the pyramid might activate similar representations at the lowest levels of the hierarchy, yet the combinations of these features into a shape produces distinct representations at higher levels of the processing hierarchy. One way to investigate how we encode shapes is to identify areas of the brain that are active when comparing contours that form a recognizable shape versus contours that are just squiggles. How do activity patterns in the brain change when a shape is familiar? This question emphasizes the idea that perception involves a connection between sensation and memory (recall our four guiding principles of object recognition). Researchers explored this question in a PET study designed to isolate the specific mental operations used when people viewed familiar shapes, novel shapes, or stimuli formed by scrambling the shapes to form random drawings (Kanwisher et al., 1997a). All three types of stimuli

Repeated objects

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FIGURE 6.11 Asymmetry between left and right fusiform activation to repetition effects. (a) A repetition suppression effect is observed in left ventral occipital cortex regardless of whether an object is shown from the same or a different viewpoint, consistent with a view-invariant representation. (b) In contrast, activation in the right ventral occipital cortex decreased relative to activity during the presentation of novel stimuli only when the second object was presented in the original viewpoint, consistent with a view-dependent representation.

b FIGURE 6.12 Basic elements and the different objects they canform. The same basic components (five lines) can form different items (e.g., a pentagon or a pyramid) depending on their arrangement. Although the low-level components (a) are the same, the high-level percepts (b) are distinct.

Computational Problems in Object Recognition | 233 Sample stimuli

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FIGURE 6.13 Component analysis of object recognition. (a) Stimuli for the three conditions and the mental operations required in each condition. Novel objects are hypothesized to engage processes involved in perception even when verbal labels do not exist. (b) Activation was greater for the familiar and novel objects compared to the scrambled images along the ventral surface of the occipitotemporal cortex.

should engage the early stages of visual perception, or what is called feature extraction (Figure 6.13a). To identify areas involved in object perception, a comparison can be made between responses to novel objects and responses to scrambled stimuli—as well as responses between familiar objects and scrambled stimuli—under the assumption that scrambled stimuli do not define objects per se. The memory retrieval contribution should be most evident when viewing novel or familiar objects. In the PET study, both novel and familiar stimuli led to increases in regional cerebral blood flow bilaterally in lateral occipital cortex (LOC, sometimes referred to as lateral occipital complex; Figure 6.13b). Since this study, many others have shown that the LOC is critical for shape and object recognition. Interestingly, no differences were found between the novel and familiar stimuli in these posterior cortical regions. At least within these areas, recognizing that something is unfamiliar may be as taxing as recognizing that something is familiar. When we view an object such as a dog, it may be a real dog, a drawing of a dog, a statue of a dog, or an outline of a dog made of flashing lights. Still, we recognize each one as a dog. This insensitivity to the specific visual cues that define an object is known as cue invariance. Research has shown that, for the LOC, shape seems to be the most salient property of the stimulus. In one fMRI study, participants viewed stimuli in which shapes were defined by either lines (our normal percepts) or the coherent motion of dots. When compared to

control stimuli with similar sensory properties, the LOC response was similar to the two types of object depictions (Grill-Spector et al., 2001; Figure 6.14). Thus the LOC can support the perception of the pink elephant or the plaid apple.

Grandmother Cells and Ensemble Coding An object is more than just a shape, though. Somehow we also know that one dog shape is a real dog, and the other is a marble statue. How do people recognize specific objects? Some researchers have attempted to answer this question at the level of neurons by asking whether there are individual cells that respond only to specific integrated percepts. Furthermore, do these cells code for the individual parts that define the object? When you recognize an object as a tiger, does this happen because a neuron sitting at the top of the perceptual hierarchy, having combined all of the information that suggests a tiger, then becomes active? If the object had been a lion, would the same cell have been silent, despite the similarities in shape (and other properties) between a tiger and lion? Alternatively, does perception of an object depend on the firing of a collection of cells? In this case, when you see a tiger, a group of neurons that code for different features of the tiger might become active, but only some of them are also active when you see a lion.

234 | CHAPTER 6 OFL

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FIGURE 6.14 BOLD response in lateral occipital cortex is responsive to shape, even if the boundaries of the objects are never physically presented. The BOLD response is high when an object is perceived, either defined by luminance or a correlated pattern of moving dots. The response is low when the dots move in a coherent direction or at random.

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Earlier in this chapter, we touched on the finding that cells in the inferotemporal lobe selectively respond to complex stimuli (e.g., objects, places, body parts, or faces; see Figure 6.3). This observation is consistent with hierarchical theories of object perception. According to these theories, cells in the initial areas of the visual cortex code elementary features such as line orientation and color. The outputs from these cells are combined to form detectors sensitive to higher order features such as corners or intersections—an idea consistent with the

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findings of Hubel and Wiesel (see Milestones in Cognitive Science: Pioneers in the Visual Cortex in Chapter 5). The process continues as each successive stage codes more complex combinations (Figure 6.15). The type of neuron that can recognize a complex object has been called a gnostic unit (from the Greek gnostikos, meaning “of knowledge”), referring to the idea that the cell (or cells) signals the presence of a known stimulus—an object, a place, or an animal that has been encountered in the past.

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FIGURE 6.15 The hierarchical coding hypothesis. Elementary features are combined to create objects that can be recognized by gnostic units. At the lowest level of the hierarchy are edge detectors, which operate similarly to the simple cells discussed in Chapter 5. These feature units combine to form corner detectors, which in turn combine to form cells that respond to even more complex stimuli, such as surfaces. The left-hand panel shows hypothesized computational stages for hierarchical coding. The right-hand panel is a cartoon of neural implementation of the computational stages illustrated in the left-hand panel.

Computational Problems in Object Recognition | 235 It is tempting to conclude that the cell represented by the recordings in Figure 6.3 signals the presence of a hand, independent of viewpoint. Other cells in the inferior temporal cortex respond preferentially to complex stimuli such as jagged contours or fuzzy textures. The latter might be useful for a monkey, in order to identify that an object has a fur-covered surface and therefore, might be the backside of another member of its group. Even more intriguing, researchers have discovered cells in the inferotemporal gyrus and the floor of the superior temporal sulcus that are selectively activated by faces. In a tonguein-cheek manner, they coined the term grandmother cell to convey the notion that people’s brains might have a gnostic unit that becomes excited only when their grandmother comes into view. Other gnostic units would be specialized to recognize, for example, a blue Volkswagen or the Golden Gate Bridge. Itzhak Fried and his colleagues at the University of California, Los Angeles, explored this question by making single-cell recordings in human participants (Quiroga et al., 2005). The participants in their study all had epilepsy; and, in preparation for a surgical procedure to alleviate their symptoms, they each had electrodes surgically implanted in their temporal lobe. In the study, participants were shown a wide range of pictures including animals, objects, landmarks, and individuals. The investigators’ first observation was that, in general, it was difficult to make these cells respond. Even when the stimuli were individually tailored to each participant based on an interview to determine that person’s visual history, the temporal lobe cells were generally inactive. Nonetheless, there were exceptions. Most notable, these exceptions revealed an extraordinary degree of stimulus specificity. Recall Figure 3.21, which shows the response of one temporal lobe neuron that was selectively activated in response to photographs of the actress Halle Berry. Ms. Berry could be wearing sunglasses, sporting dramatically different haircuts, or even be in costume as Catwoman from one of her movie roles—but in all cases, this particular neuron was activated. Other actresses or famous people failed to activate the neuron. Let’s briefly return to the debate between grandmother-cell coding versus ensemble coding. Although you might be tempted to conclude that cells like these are gnostic units, it is important to keep in mind the limitations of such experiments. First, aside from the infinite number of possible stimuli, the recordings are performed on only a small subset of neurons. As such, this cell potentially could be activated by a broader set of stimuli, and many other neurons might respond in a similar manner. Second, the results also suggest that these gnostic-like units are not really “perceptual.” The same cell was also

activated when the words Halle Berry were presented. This observation takes the wind out of the argument that this is a grandmother cell, at least in the original sense of the idea. Rather, the cell may represent the concept of “Halle Berry,” or even represent the name Halle Berry, a name that is likely recalled from memory for any of the stimuli relevant to Halle Berry. Studies like this pose three problems for the traditional grandmother-cell hypothesis: 1. The idea of grandmother cells rests on the assumption that the final percept of an object is coded by a single cell. Because cells are constantly firing and refractory, a coding scheme of this nature would be highly susceptible to error. If a gnostic unit were to die, we would expect to experience a sudden loss for an object. You would pass grandma (or Halle Berry) on the street without a second thought. 2. The grandmother-cell hypothesis cannot adequately account for how it is possible to perceive novel objects. 3. Third, the gnostic theory does not account for how the grandmother cell would have to adapt as grandmother changed over time. Granny may have had a face-lift, dumped her glasses after corrective eye surgery, dyed her hair, and lost 30 pounds on a low-carb diet. Actually. . . in that case, you might have a problem recognizing her. One alternative to the grandmother-cell hypothesis is that object recognition results from activation across complex feature detectors (Figure 6.16). Granny, then, is recognized when some of these higher order neurons are activated. Some of the cells may respond to her shape, others to the color of her hair, and still others to the features of her face. According to this ensemble hypothesis, recognition is not due to one unit but to the collective activation of many units. Ensemble theories readily account for why we can recognize similarities between objects (say, the tiger and lion) and may confuse one visually similar object with another: Both objects activate many of the same neurons. Losing some units might degrade our ability to recognize an object, but the remaining units might suffice. Ensemble theories also account for our ability to recognize novel objects. Novel objects bear a similarity to familiar things, and our percept results from activating units that represent their features. The results of single-cell studies of temporal lobe neurons are in accord with ensemble theories of object recognition. Although it is striking that some cells are selective for complex objects, the selectivity is almost always relative, not absolute. The cells in the inferotemporal cortex prefer certain stimuli to others, but they are also

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activated by visually similar stimuli. The cell represented in Figure 6.3, for instance, increases its activity when presented with a mitten-like stimulus. No cells respond to a particular individual’s hand; the hand-selective cell responds equally to just about any hand. In contrast, as people’s perceptual abilities demonstrate, we make much finer discriminations.

Summary of Computational Problems We have considered several computational problems that must be solved by an object recognition system. Information is represented on multiple scales. Although early visual input can specify simple features, object perception involves intermediate stages of representation in which features are assembled into parts. Objects are not determined solely by their parts, though; they also are defined by the relationship between the parts. An arrow and the letter Y contain the same parts but differ in their arrangement. For object recognition to be flexible and robust, the perceived spatial relations among parts should not vary across viewing conditions.

TAKE-HOME MESSAGES ■

Object constancy refers to the ability to recognize objects in countless situations, despite variation in the physical stimulus.

Object perception may occur in a view-dependent frame of reference or a view-invariant frame of reference. In view-dependent theories, perception is assumed to be specific to a particular viewpoint. View-invariant theories posit that recognition occurs at a level that is not linked to specific stimulus information.

Face shape

Wrinkles

The lateral occipital cortex is critical for the recognition of the shape of an object.

The term grandmother cell has been coined to convey the notion that recognition arises from the activation of neurons that are finely tuned to specific stimuli.

Ensemble theories, on the other hand, hypothesize that recognition is the result of the collective activation of many neurons.

Failures in Object Recognition: The Big Picture Now that we have some understanding of how the brain processes visual stimuli in order to recognize objects, let’s return to our discussion of agnosia. Many people who have suffered a traumatic neurological insult, or who have a degenerative disease such as Alzheimer’s, may experience problems recognizing things. This is not necessarily a problem of the visual system. It could be the result of the effects of the disease or injury on attention, memory, and language. Unlike someone with visual agnosia, for a person with Alzheimer’s disease, recognition failures persist even when an object is placed in their hands or if it is verbally described to them. As noted earlier, people with visual agnosia have difficulty recognizing objects that are presented visually or require the use of visually based representations. The key word is visual—these patients’ deficit is restricted to the visual domain. Recognition through other sensory modalities, such as touch or audition, is typically just fine. Like patient G.S., who was introduced at the beginning of this chapter, visual agnostics can look at a fork yet fail to recognize it as a fork. When the object is placed in their hands, however, they will immediately recognize it (Figure 6.17a). Indeed, after touching the object, an agnosia patient may actually report seeing the object clearly. Because the patient can recognize the object through Hair other modalities, and through vision with supplementary support, we know that the problem does not reflect a general

Mouth

FIGURE 6.16 The ensemble coding hypothesis. Objects are defined by the simultaneous activation of a set of defining properties. “Granny” is recognized here by the co-occurrence of her wrinkles, face shape, hair color, and so on.

Failures in Object Recognition: The Big Picture | 237 Agnosia

a Memory loss

the detection of shape, features, color, motion, and so on. The current literature broadly distinguishes between three major subtypes of agnosia: apperceptive agnosia, integrative agnosia, and associative agnosia, roughly reflecting the idea that object recognition problems can arise at different levels of processing. Keep in mind, though, that specifying subtypes can be a messy business, because the pathology is frequently extensive and because a complex process such as object recognition, by its nature, involves a number of interacting component processes. Diagnostic categories are useful for clinical purposes, but generally have limited utility when these neurological disorders are used to build models of brain function. With that caveat in mind, we can now look at each of these forms of agnosia in turn.

Apperceptive Agnosia

b FIGURE 6.17 Agnosia versus memory loss. To diagnose an agnosic disorder, it is essential to rule out general memory problems. (a) The patient with visual agnosia is unable to recognize a fork by vision alone but immediately recognizes it when she picks it up. (b) The patient with a memory disorder is unable to recognize the fork even when he picks itup.

loss of knowledge. Nor does it represent a loss of vision, for they can describe the object’s physical characteristics such as color and shape. Thus, their deficit reflects either a loss of knowledge limited to the visual system or a disruption in the connections between the visual system and modality-independent stores of knowledge. So, we can say that the label visual agnosia is restricted to individuals who demonstrate object recognition problems even though visual information continues to be registered at the cortical level. The 19th-century German neurologist Heinrich Lissauer was the first to suggest that there were distinct subtypes of visual object recognition deficits. He distinguished between recognition deficits that were sensory based and those that reflected an inability to access visually directed memory—a disorder that he melodramatically referred to as Seelenblindheit, or “soul blindness” (Lissauer, 1890). We now know that classifying agnosia as sensory based is not quite correct, at least not if we limit “sensory” to processes such as

Apperceptive agnosia can be a rather puzzling disorder. A standard clinical evaluation of visual acuity may fail to reveal any marked problems. The patient may perform normally on shape discrimination tasks and even have little difficulty recognizing objects, at least when presented from perspectives that make salient the most important features. The object recognition problems become evident when the patient is asked to identify objects based on limited stimulus information, either because the object is shown as a line drawing or seen from an unusual perspective. Beginning in the late 1960s, Elizabeth Warrington embarked on a series of investigations of perceptual disabilities in patients possessing unilateral cerebral lesions caused by a stroke or tumor (Warrington & Rabin, 1970; Warrington, 1985). Warrington devised a series of tests to look at object recognition capabilities in one group of approximately 70 patients (all of whom were righthanded and had normal visual acuity). In a simple perceptual matching test, participants had to determine if two stimuli, such as a pattern of dots or lines, were the same or different. Patients with right-sided parietal lesions showed poorer performance than did either control subjects or patients with lesions of the left hemisphere. Left-sided damage had little effect on performance. This result led Warrington to propose that the core problem for patients with right-sided lesions involved the integration of spatial information (see Chapter 4). To test this idea, Warrington devised the Unusual Views Object Test. Participants were shown photographs of 20 objects, each from two distinct views (Figure 6.18a). In one photograph, the object was oriented in a standard or prototypical view; for example, a cat was photographed with its head facing forward. The other photograph depicted an unusual or atypical view; for example, the cat was photographed from behind, without its face or feet in

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Auditory Agnosia Other sensory modalities besides visual perception surely contribute to object recognition. Distinctive odors in a grocery store enable us to determine which bunch of greens is thyme and which is basil. Using touch, we can differentiate between cheap polyester and a fine silk garment. We depend on sounds, both natural and human-made, to cue our actions. A siren prompts us to search for a nearby police car or ambulance, or anxious parents immediately recognize the cries of their infant and rush to the baby’s aid. Indeed, we often overlook our exquisite auditory capabilities for object recognition. Have a friend rap on a wooden tabletop, or metal filing cabinet, or glass window. You will easily distinguish between these objects. Numerous studies have documented failures of object recognition in other sensory modalities. As with visual agnosia, a patient has to meet two criteria to be labeled agnosic. First, a deficit in object recognition cannot be secondary to a problem with perceptual processes. For example, to be classified as having auditory agnosia, patients must perform within normal limits on tests of tone detection; that is, the loudness of a sound that’s required for the person to detect it must fall within a normal range. Second, the deficit in recognizing objects must be restricted to a single modality. For example, a patient who cannot identify environmental sounds such as the ones made by flowing water or jet engines must be able to recognize a picture of a waterfall or an airplane. Consider a patient, C.N., reported by Isabelle Peretz and her colleagues (1994) at the University of Montreal. A 35-year-old nurse, C.N. had suffered a ruptured aneurysm in the right middle cerebral artery, which was repaired. Three months later, she was diagnosed with a second aneurysm, in the left middle cerebral artery which also required surgery. Postoperatively, C.N.’s abilities to detect tones and to comprehend and produce speech were not impaired. But she immediately complained that her perception of music was deranged. Her amusia, or impairment in music abilities, was verified by tests. For example, she could not recognize melodies taken from her personal

record collection, nor could she recall the names of 140 popular tunes, including the Canadian national anthem. C.N.’s deficit could not be attributed to a problem with long-term memory. She also failed when asked to decide if two melodies were the same or different. Evidence that the problem was selective to auditory perception was provided by her excellent ability to identify these same songs when shown the lyrics. Similarly, when given the title of a musical piece such as The Four Seasons, C.N. responded that the composer was Vivaldi and could even recall when she had first heard the piece. Just as interesting as C.N.’s amusia was her absence of problems with other auditory recognition tests. C.N. understood speech, and she was able to identify environmental sounds such as animal cries, transportation noises, and human voices. Even within the musical domain, C.N. did not have a generalized problem with all aspects of music comprehension. She performed as well as normal participants when asked to judge if two-tone sequences had the same rhythm. Her performance fell to a level of near chance, however, when she had to decide if the two sequences were the same melody. This dissociation makes it less surprising that, despite her inability to recognize songs, she still enjoyed dancing! Other cases of domain-specific auditory agnosia have been reported. Many patients have an impaired ability to recognize environmental sounds, and, as with amusia, this deficit is independent of language comprehension problems. In contrast, patients with pure word deafness cannot recognize oral speech, even though they exhibit normal auditory perception for other types of sounds and have normal reading abilities. Such category specificity suggests that auditory object recognition involves several distinct processing systems. Whether the operation of these processes should be defined by content (e.g.,verbal versus nonverbal input) or by computations (e.g., words and melodies may vary with regard to the need for part-versus-whole analysis) remains to be seen . . . or rather heard.

the picture. Participants were asked to name the objects shown. Although normal participants made few, if any, errors, patients with right posterior lesions had difficulty identifying objects that had been photographed from unusual orientations. They could name the objects photographed in the prototypical orientation, which confirmed that their problem was not due to lost visual knowledge. This impairment can be understood by going back to our earlier discussion of object constancy. A hallmark of human

perceptual systems is that from an infinite set of percepts, we readily extract critical features that allow us to identify objects. Certain vantage points are better than others, but the brain is designed to overcome variability in the sensory input to recognize both similarities and differences between different inputs. The ability to achieve object constancy is compromised in patients with apperceptive agnosia. Although these patients can recognize objects, this ability diminishes when the perceptual input is limited (as with

Failures in Object Recognition: The Big Picture | 239

shadows; Figure 6.18b) or does not include the most salient features (as with atypical views). The finding that this type of disorder is more common in patients with right-hemisphere lesions suggests that this hemisphere is essential for the operations required to achieve object constancy.

a

Unusual-views test

100 Left hemisphere Right hemisphere Percentage correct

FIGURE 6.18 Tests used to identify apperceptive agnosia. (a) In the unusual-views test, participants must judge whether two images seen from different vantage points show the same object. (b) In the shadows test, participants must identify the object(s) when seen under normal or shadowed illumination. In both tests, patients with right-hemisphere lesions, especially in the posterior area, performed much worse than did control participants (not shown) or patients with left-hemisphere lesions.

90

Patients with right-hemisphere lesions, especially in the posterior area, performed much worse than patients with left-hemisphere lesions.

80

70 Anterior damage Posterior damage Patient group b

Shadows test 100 Left hemisphere

Integrative Agnosia

Percentage correct

Right hemisphere 90

People with integrative agnosia are unable to integrate features into parts, or parts of an object into a coherent whole. 80 This classification of agnosia was first Patients with right-hemisphere suggested by Jane Riddoch and Glyn lesions, especially in the posterior Humphreys following an intensive case area, performed much worse than study of one patient, H.J.A. The patient patients with left-hemisphere lesions. 70 had no problem doing shape-matching Anterior damage Posterior damage tasks and, unlike with apperceptive agPatient group nosia, was successful in matching photographs of objects seen from unusual views. His object recognition problem, however, became apparent when he was asked to identify objects that overlapped one another (Humphreys & Riddoch, 1987; Humphreys et al., 1994). He was either at a loss to describe what he saw, or would build a per1 8 cept only step-by-step. Rather than perceive an object at a glance, H.J.A. relied on recognizing salient features or 2 parts. To recognize a dog, he would perceive each of the 9 4 3 5 legs, the characteristic shape of the body and head, and then use these part representations to identify the whole object. Such a strategy runs into problems when objects 10 6 overlap, because the observer must not only identify the 7 parts but also correctly assign parts to objects. b a A telling example of this deficit is provided by the FIGURE 6.19 Patients with integrative agnosia do not see drawings of another patient with integrative agnosia— objects holistically. C.K., a young man who suffered a head injury in an auPatient C.K. was asked to copy the figure shown in (a). His tomobile accident (Behrmann et al., 1994). C.K. was overall performance (b) was quite good; the two diamonds and shown a picture consisting of two diamonds and one the circle can be readily identified. However, as noted in the circle in a particular spatial arrangement and asked text, the numbers indicate the order he used to produce the segments. to reproduce the drawing (Figure 6.19). Glance at the

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drawing in Figure 6.19b—not bad, right? But now look at the numbers, indicating the order in which C.K. drew the segments to form the overall picture. After starting with the left-hand segments of the upper diamond, C.K. proceeded to draw the upper left-hand arc of the circle and then branched off to draw the lower diamond before returning to complete the upper diamond and the rest of the circle. For C.K., each intersection defined the segments of different parts. He failed to link these parts into recognizable wholes—the defining characteristic of integrative agnosia. Other patients with integrative agnosia are able to copy images perfectly, but cannot tell you what they are. Object recognition typically requires that parts be integrated into whole objects. The patient described at the beginning of this chapter, G.S., exhibited some features of integrative agnosia. He was fixated on the belief that the combination lock was a telephone because of the circular array of numbers, a salient feature (part) on the standard rotary phones of his time. He was unable to integrate this part with the other components of the combination lock. In object recognition, the whole truly is greater than the sum of its parts.

Associative Agnosia Associative agnosia is a failure of visual object recognition that cannot be attributed to a problem of integrating parts to form a whole, or to a perceptual limitation, such as a failure of object constancy. A patient with associative agnosia can perceive objects with his visual system, but cannot understand or assign meaning to the objects. Associative agnosia rarely exists in a pure form; patients often perform abnormally on tests of basic perceptual abilities, likely because their lesions are not highly localized. Their perceptual deficiencies, however, are not proportional to their object recognition problem. For instance, one patient, F.R.A., awoke one morning and discovered that he could not read his newspaper—a condition known as alexia, or acquired alexia (R. McCarthy & Warrington, 1986). A CT scan revealed an

infarct of the left posterior cerebral artery. The lesioned area was primarily in the occipital region of the left hemisphere, although the damage probably extended into the posterior temporal cortex. F.R.A. could copy geometric shapes and could point to objects when they were named. Notably, he could segment a complex drawing into its parts (Figure 6.20). Apperceptive and integrative agnosia patients fail miserably when instructed to color each object differently. In contrast, F.R.A. performed the task effortlessly. Despite this ability, though, he could not name the objects that he had colored. When shown line drawings of common objects, he could name or describe the function of only half of them. When presented with images of animals that were depicted to be the same size, such as a mouse and a dog, and asked to point to the larger one, his performance was barely above chance. Nonetheless, his knowledge of such properties was intact. If the two animal names were said aloud, F.R.A. could do the task perfectly. Thus his recognition problems reflected an inability to access that knowledge from the visual modality. Associative agnosia is reserved for patients who derive normal visual representations but cannot use this information to recognize things. Recall that in the Unusual Views Object Test, study participants are required to judge if two pictures depict the same object from different orientations. This task requires participants to categorize information according to perceptual qualities. In an alternative task, the Matching-by-Function Test, participants are shown three pictures and asked to point to the two that are functionally similar. In Figure 6.21, the correct response in the top panel is to match the closed umbrella to the open umbrella, even though the former is physically more similar to the cane. In the bottom panel, the director’s chair should be matched with the beach chair, not the more similar looking wheelchair. The Matching-by-Function Test requires participants to understand the meaning of the object, regardless of its appearance. Patients with posterior lesions in either the right or the left hemisphere are impaired on this task. When considered in conjunction with other tasks used by Warrington, it

FIGURE 6.20 Alexia patient F.R.A.’s drawings. Despite his inability to name visually presented objects, F.R.A. was quite successful in coloring in the components of these complex drawings. He had clearly succeeded in parsing the stimuli but still was unable to identify the objects.

Category Specificity in Agnosia: The Devil Is in the Details | 241 tional connection between the two visual percepts. They lack access to the conceptual representations needed to link the functional association between the open and closed umbrellas. This is associative agnosia.

TAKE-HOME MESSAGES ■

Apperceptive agnosia can be considered a problem in achieving object constancy. The patient with apperceptive agnosia may recognize an object from a typical viewpoint, but performance deteriorates when asked to name an object that is seen from an unusual viewpoint or is occluded by shadows.

Integrative agnosia is a deficit that arises from the inability to integrate features into parts, or parts of an object into a coherent whole.

Associative agnosia describes patients who are unable to access conceptual knowledge from visual input. Their perceptual abilities may be (relatively) intact, but they fail to link that representation to knowledge about what the object is used for, where it might be found, and so on.

Category Specificity in Agnosia: The Devil Is in the Details Categorizing agnosia into apperceptive, associative, and integrative is helpful for understanding the processes involved with object recognition. Further insight has come from seemingly bizarre cases of agnosia in which the patients exhibit object recognition deficits that are selective for specific categories of objects. These cases have shown that there is more to visual agnosia than meets the eye.

Animate Versus Inanimate? FIGURE 6.21 Matching-by-Function Test. Participants are asked to choose the two objects that are most similar in function.

appears that the problems in the two groups happen for different reasons. Patients with right-sided lesions cannot do the task because they fail to recognize many objects, especially those depicted in an unconventional manner such as the closed umbrella. This is apperceptive agnosia. Patients with left-sided lesions cannot make the func-

We have learned that associative agnosia results from the loss of semantic knowledge regarding the visual structures or properties of objects. Early perceptual analyses proceed normally, but the long-term knowledge of visual information is either lost or can’t be accessed; thus, the object cannot be recognized. Consider, however, the case of patient J.B.R. J.B.R. was diagnosed with herpes simplex encephalitis. His illness left him with a complicated array of deficits, including profound amnesia and word-finding difficulties. His performance on tests of apperceptive agnosia was normal, but he had a severe associative agnosia. Most notably, his agnosia was disproportionately

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Visual Perception, Imagery, and Memory Stop reading for a minute and imagine yourself walking along the beach at sunset. Got it? Most likely your image is of a specific place where you once enjoyed an ocean sunset. Some details may be quite salient and others may require further reflection. Were any boats passing by on the horizon in the image? Was the surf calm or rough; were the gulls squawking; was it cloudy? When we imagine our beachside sunset, are we activating the same neural pathways and performing the same internal operations as when we gaze upon such a scene with our eyes? Probably. Neuropsychological research provides compelling evidence of shared processing for imagery and perception. Patients with perceptual deficits have also been shown to have corresponding deficits in imagery (Farah, 1988). Strokes may isolate visual information from areas that represent more abstract knowledge, causing difficulty in both perception and imagery tasks. For example, one patient was able to sort objects according to color, but when asked to name a color or point to a named color, her performance was impaired. With imagery tasks, the patient also could not answer questions about the colors of objects. She could say that a banana is a fruit that grows in southern climates but could not name its color. Even more surprising, the patient answered metaphorical questions about colors. For example, she could answer the question “Whatis the color of envy?” by responding, “Green.” Questions like these cannot be answered through imagery. Patients with higher order visual deficits have related deficits in visual imagery. For instance, one patient with occipitotemporal lesions had difficulty imagining faces or animals, but he could readily draw a floor plan of his house and locate major cities on a map of the United States. In contrast, another patient with damage to the parietal-occipital pathways produced vivid descriptions when he was asked to imagine objects, but he failed spatial imagery tasks. Together, these patients provide evidence of dissociation in imagery of what–where processing that closely parallels the dissociation observed in perception. The evidence provides a compelling case that mental imagery uses many of the same processes that are critical for perception. The sights in an image are likely to activate visual areas of the brain; the sounds, auditory areas; and the smells, olfactory areas. Indeed, in one fMRI study, approximately 90% of the voxels showed correlated activation patterns during perception and imagery, even if the magnitude of the signal was larger during perception (Ganis et al., 2005). Despite the similarities between perception and imagery, the two are not identical. We know when we are imagining the Spanish Steps in Rome that we are not really there. The inability to distinguish between real and imagined states of mind has been hypothesized to underlie certain psychiatric conditions such as schizophrenia. One provocative issue that has received relatively little attention is how visual memory changes over time following

damage to systems involved in visual perception. If we are deprived of consistent input, then it seems reasonable to expect that our knowledge base will be reorganized. In his essay “The Case of the Colorblind Painter,” Oliver Sacks (1995) described Mr. I, a successful artist who suffered complete achromatopsia (loss of color vision) following a car accident. A lover of color, he was horrified upon returning to his studio to discover that all of his vividly colored abstract paintings now appeared a morass of grays, blacks, and whites. Food was no longer appetizing given that the colors of tomatoes, carrots, and broccoli all were varying shades of gray. Even sex became repugnant after he viewed his wife’s flesh, and indeed his own flesh, as a “rat-colored” gray. No doubt most of us would agree with Mr.I’s initial description of his visual world: “awful, disgusting.” Interestingly, his shock underscores the fact that his color knowledge was still intact. Mr. I could remember with great detail the colors he expected to see in his paintings. It was the mismatch between his expectation and what he saw that was so depressing. He shunned museums because the familiar pictures just looked wrong. During the subsequent year, however, a transition occurred. Mr. I’s memory for colors started to slip away. He no longer despaired when gazing at a tomato devoid of red or a sunset drained of color. He knew that something wasn’t quite right, but his sense of the missing colors was much vaguer. Indeed, he began to appreciate the subtleties of a black-and-white world. Overwhelmed by the brightness of the day, Mr. I became a night owl, appreciating forms in purity, “uncluttered by color.” This change can be seen in his art (Figure 1). Prior to the accident, Mr. I relied on color to create subtle boundaries, to evoke movement across the canvas. In his black-and-white world, geometric patterns delineated sharp boundaries.

FIGURE 1 An abstract painting by Mr. I, produced 2 years after his accident. Mr. I was experimenting with colors at this time, although he was unable to see them.

Category Specificity in Agnosia: The Devil Is in the Details | 243 worse for living objects than for inanimate ones. When he was shown drawings of common objects, such as scissors, clocks, and chairs, and asked to identify them, his success rate was about 90 %. Show him a picture of a tiger or a blue jay, however, and he was at a loss. He could correctly identify only 6 % of the pictures of living things. Other patients with agnosia have reported a similar dissociation for living and nonliving things (Satori & Job, 1988).

Sensorimotor areas

Organizational Theories of Category Specificity How are we to interpret such puzzling deficits? If we assume that associative agnosia represents a loss of knowledge about visual properties, we might suppose that a category-specific disorder results from the selective loss within, or a disconnection from, this knowledge system. We recognize that birds, dogs, and dinosaurs are animals because they share common features. In a similar way, scissors, saws, and knives share characteristics. Some might be physical (e.g., they all have an elongated shape) and others functional (e.g., they all are used for cutting). Brain injuries that produce agnosia in humans do not completely destroy the connections to semantic knowledge. Even the most severely affected patient will recognize some objects. Because the damage is not total, it seems reasonable that circumscribed lesions might destroy tissue devoted to processing similar types of information. Patients with category-specific deficits support this form of organization. J.B.R.’s lesion appeared to affect regions associated with processing information about living things. If this interpretation is valid, we should expect to find patients whose recognition of nonliving things is disproportionately impaired. Reports of agnosia patients exhibiting this pattern, however, are much rarer. There could be an anatomical reason for the discrepancy. For instance, regions of the brain that predominantly process or store information about animate objects could be more susceptible to injury or stroke. Alternatively, the dissociation could be due to differences in how we perceive animate and inanimate objects. One hypothesis is that many nonliving things evoke representations not elicited by living things (A. Damasio, 1990). In particular, manufactured objects can be manipulated. As such, they are associated with kinesthetic and motoric representations. When viewing an inanimate object, we can activate a sense of how it feels or of the actions required to manipulate it (Figure 6.22). Corresponding representations may not exist for living objects. Although we may have a kinesthetic sense

1˚ Visual cortex

FIGURE 6.22 Sensorimotor areas assist in object recognition. Our visual knowledge of many inanimate objects is supplemented by kinesthetic codes developed through our interactions with these objects. When a picture of scissors is presented to a patient with an object-specific deficit, the visual code may not be sufficient for recognition. When the picture is supplemented with priming of kinesthetic codes, however, the person is able to name the object. Kinesthetic codes are unlikely to exist for most living things.

of how a cat’s fur feels, few of us have ever stroked or manipulated an elephant. We certainly have no sense of what it feels like to pounce like a cat or fly like a bird. According to this hypothesis, manufactured objects are easier to recognize because they activate additional forms of representation. Although brain injury can produce a common processing deficit for all categories of stimuli, these extra representations may be sufficient to allow someone to recognize nonliving objects. This hypothesis is supported by patient G.S.’s behavior. Remember that when G.S. was shown the picture of the combination lock, his first response was to call it a telephone. Even when he was verbalizing “telephone,” however, his hands began to move as if they were opening a combination lock. Indeed, he was able to name the object after he looked at his hands and realized what they were trying to tell him. Neuroimaging studies in healthy participants provide converging support for this hypothesis. When people view pictures of manufactured objects such as tools, the left ventral premotor cortex, a region associated with action planning, is activated. Moreover, this region is activated when the stimuli are pictures of natural objects that can be grasped and manipulated, such as a rock (Gerlach et al., 2002; Kellenbach et al., 2003). These results suggest that this area of the brain responds preferentially to

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action knowledge, or the knowledge of how we interact with objects. Martha Farah and Jay McClelland (1991) used a series of computer simulations to integrate some of these ideas. Their study was designed to contrast two ways of conceptualizing the organization of semantic memory of objects. Semantic memory refers to our conceptual knowledge of the world, the facts or propositions that arise from our experience (e.g., that a steamroller is used to flatten roads—information you may have, even though you probably have never driven a steamroller; Figure 6.23a). One hypothesis is that semantic memory is organized by category membership. According to this hypothesis, there are distinct representational systems for living and nonliving things, and perhaps further subdivisions within these two broad categories. An alternative hypothesis is

u

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les

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a

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l

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s Tools

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al

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Veh ic

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gt hing

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gs

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tio Func

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Verbal name

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Visual picture

FIGURE 6.23 Two hypotheses about the organization of semantic knowledge. (a) A category-based hypothesis (left) proposes that semantic knowledge is organized according to our categories of the world. For example, one prominent division would put living things in one group and nonliving things in another. A property-based hypothesis (right) proposes that semantic knowledge is organized according to the properties of objects. These properties may be visual or functional. (b)The architecture of Farah and McClelland’s connectionist model of a property-based semantic system. The initial activation for each object is represented by a unique pattern of activation in two input systems and the semantic system. In this example, the darkened units would correspond to the pattern for one object. The final activation would be determined by the initial pattern and the connection weights between the units. There are no connections between the two input systems. The names and pictures are linked through the semantic system.

that semantic memory reflects an organization based on object properties. The idea that nonliving things are more likely to entail kinesthetic and motor representations is one variant of this view. The computer simulations were designed to demonstrate that category-specific deficits, such as animate and inanimate, could result from lesions to a semantic memory system organized by object properties. In particular, the simulations focused on the fact that living things are distinguished by their visual appearance, whereas nonliving things are also distinguished by their functional attributes. The architecture of Farah and McClelland’s model involved a simple neural network, a computer model in which information is distributed across a number of processing units (Figure 6.23b). One set of units corresponded to peripheral input systems, divided into a verbal and a visual system. Each of these was composed of 24 input units. The visual representation of an object involved a unique pattern of activation across the 24 visual units. Similarly, the name of an object involved a unique pattern of activation across the 24 verbal units. Each object was also linked to a unique pattern of activation across the second type of unit in the model: the semantic memory. Within the semantic system were two types of units: visual and functional (see Figure 6.23b). Although these units did not correspond to specific types of information (e.g., colors or shapes), the idea here is that semantic knowledge consists of at least two types of information. One type of semantic knowledge is visually based; for example, a tiger has stripes or a chair has legs. The other type of semantic memory corresponds to people’s functional knowledge of objects. For example, functional semantics would include our knowledge that tigers are dangerous or that a chair is a type of furniture. To capture psychological differences in how visual and functional information might be stored, the researchers imposed two constraints on semantic memory: The first constraint was that, of the 80 semantic units, 60 were visual and 20 were functional. This 3:1 ratio was based on a preliminary study in which human participants were asked to read the dictionary definitions of living and nonliving objects and indicate whether a descriptor was visual or functional. On average, three times as many descriptors were classified as visual. Second, the preliminary study indicated that the ratio of visual to functional descriptors differed for the two classes of objects. For living objects the ratio was 7.7:1, but for nonliving objects this ratio dropped to 1.4:1. Thus, as discussed previously, our knowledge of living objects is much more dependent on visual information than is our knowledge of nonliving objects. In

Category Specificity in Agnosia: The Devil Is in the Details | 245 the model, this constraint dictated the number of visual and functional semantic units used for the living and nonliving objects being varied. The model was trained to link the verbal and visual representations of a set of 20 objects, half of them living and the other half nonliving. Note that the verbal and visual units were not directly linked, but could interact only through their connections with the semantic system. The strength of these connections was adjusted in a training procedure. This procedure was not intended to simulate how people acquire semantic knowledge. Rather, the experimenters set all of the units—both input and semantic—to their values for a particular object and then allowed the activation of each unit to change

100 Nonliving Percentage correct

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20 40 60 80 Percentage of units damaged in functional semantic memory

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FIGURE 6.24 Measuring category-specific deficits in a neural network. Lesions in the semantic units resulted in a double dissociation between the recognition of living and nonliving objects. After a percentage of the semantic units were eliminated, two measurements were made. (a) When the lesion was restricted to the visual semantic memory units, the model showed a marked impairment in correctly identifying living things. (b) When the lesion was restricted to the functional semantic memory units, the impairment was much milder and limited to nonliving things.

depending on both its initial activation and the input it received from other units. Then, to minimize the difference between the resulting pattern and the original pattern, the experimenters adjusted the connection weights. The model’s object recognition capabilities could be tested by measuring the probability of correctly associating the names and pictures. This model proved extremely adept. After 40 training trials, it was perfect when tested with stimuli from either category: living or nonliving. The key question centered on how well the model did after receiving “lesions” to its semantic memory—lesions assumed to correspond to what happens in patients with visual associative agnosia. Lesions in a model consist of the deactivation of a certain percentage of the semantic units. As Figure 6.24 shows, selective lesions in either the visual (a) or the functional (b) semantic system produced category-specific deficits. When the damage was restricted to visual semantic memory, the model had great difficulty associating the names and pictures correctly for living objects. In contrast, when the damage was restricted to functional semantic memory, failures were limited to nonliving objects. Moreover, the “deficits” are much more dramatic in the former simulation, consistent with the observation that patients are more likely to have selective deficits in recognizing living things compared to selective deficits in recognizing non-living things. This result meshes nicely with reports in the neuropsychological literature that there are many more instances of patients with a category-specific agnosia for living things. Even when functional semantic memory was damaged, the model remained proficient in identifying nonliving objects, presumably because knowledge of these objects was distributed across both the visual and the functional memory units. These simulations demonstrate how category-specific deficits might reflect the organization of semantic memory knowledge. The modeling work makes an important point: We need not postulate that our knowledge of objects is organized along categories such as living and nonliving. The double dissociation between living and nonliving things has been taken to suggest that humans have specialized systems sensitive to these categorical distinctions. Although this organization is possible, the Farah and McClelland model shows that the living–nonliving dissociation can occur even when a single system is used to recognize both living and nonliving things. Rather than assuming a partitioning of representational systems based on the type of object, Farah and McClelland proposed that semantic memory is organized according to the properties that define the objects. We will return to this question a bit later in the chapter.

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Prosopagnosia Is a Failure to Recognize Faces It’s hard to deny—one of the most important objects that people recognize, living or otherwise, is faces. Though we may have characteristic physiques and mannerisms, facial features provide the strongest distinction between people. The importance of face perception is reflected in our extraordinary ability to remember faces. When we browse through old photos, we readily recognize the faces of people we have not seen for many years. Unfortunately, our other memory abilities are not as keen. Although we may recall that the person in a photograph was in our third-grade class, her name may remain elusive. Of course, it does not take years to experience this frustration; fairly often, we run into an acquaintance whose face is familiar but are unable to remember her name or where and when we previously met. Prosopagnosia is the term used to describe an impairment in face recognition. Given the importance of face recognition, prosopagnosia is one of the most fascinating and disturbing disorders of object recognition. As with all other visual agnosias, prosopagnosia requires that the deficit be specific to the visual modality. Like patient P.T., described at the beginning of the last chapter, patients with prosopagnosia are able to recognize a person upon hearing that person’s voice. One prosopagnosic patient with bilateral occipital lesions failed to identify not only his wife but also an even more familiar person—himself (Pallis, 1955). As he reported, “At the club I saw someone strange staring at me, and asked the steward who it was. You’ll laugh at me. I’d been looking at myself in the mirror” (Farah, 2004, p. 93). Not surprisingly, this patient was also unable to recognize pictures of famous individuals of his time, including Churchill, Hitler, Stalin, Marilyn Monroe, and Groucho Marx. This deficit was particularly striking because in other ways the patient had an excellent memory, recognized common objects without hesitation, and could read and recognize line drawings—all tests that agnosia patients often fail. The study of prosopagnosia has been driven primarily by the study of patients with brain lesions. These cases provide striking examples of the abrupt loss of an essential perceptual ability. More recently, researchers have been interested in learning if this condition is also evident in individuals with no history of neurological disturbance. The inspiration here comes from the observation that people show large individual differences in their ability to recognize faces. Recent studies suggest that some individuals can be considered to have congenital prosopagnosia, that is, a lifetime problem with face perception.

A familial component has been identified in congenital prosopagnosia. Monozygotic twins (same DNA) are more similar than dizygotic twins (share only 50 % of the same DNA) in their ability to perceive faces. Moreover, this ability is unrelated to general measures of intelligence or attention (Zhu et al., 2009). Genetic analyses suggest that congenital prosopagnosia may involve a gene mutation with autosomal dominant inheritance. One hypothesis is that during a critical period of development, this gene is abnormally expressed, resulting in a disruption in the development of white matter tracts in the ventral visual pathway (see How the Brain Works: Autism and Face Perception).

Processing Faces: Are Faces Special? Face perception may not use the same processing mechanisms as those used in object recognition—a somewhat counterintuitive hypothesis. It seems more reasonable and certainly more parsimonious to assume that brains have a single, general-purpose system for recognizing all sorts of visual inputs. Why should faces be treated differently from other objects? When we meet someone, we usually look at his face to identify him. In no cultures do individuals look at thumbs or knees or other body parts to recognize one another. The tendency to focus on faces reflects behavior that is deeply embedded in our evolutionary history. Faces offer a wealth of information. They tell us about age, health, and gender. Across cultures, facial expressions also give people the most salient cues regarding emotional states, which helps us discriminate between pleasure and displeasure, friendship and antagonism, agreement and confusion. The face, and particularly the eyes, of another person can provide significant clues about what is important in the environment. Looking at someone’s lips when she is speaking helps us to understand words more than we may realize. Although these evolutionary arguments can aid in developing a hypothesis about face recognition, it is essential to develop empirical tests to either support or refute the hypothesis. A lot of data has been amassed on this problem; investigators draw evidence from studies of people with prosopagnosia, electrophysiological studies of primates, and fMRI and EEG imaging studies of healthy humans. This work is relevant not only for the question of how faces are perceived. More generally, the notion that the brain may have category-specific mechanisms is important for thinking about how it is organized. Is the brain organized as a system of specialized modules,

HOW THE BRAIN WORKS

Autism and Face Perception Autism is defined by the presentation of a constellation of unusual symptoms in the first few years of life. Autistic children fail to have normal social interactions or even an interest in such interactions. Both verbal and nonverbal language are delayed. Autistic children may exhibit repetitive and stereotyped patterns of behavior, interests, and activities. The pattern, though, is diverse from one child to the next. This heterogeneity has made it difficult for researchers to specify the underlying psychological mechanisms, and hampered efforts to identify the cause or causes of autism. Given the emphasis on problems in social interactions, there has been concerted study of face perception in people with autism. fMRI studies have revealed thatthese individuals show hypoactivity in the FFA and other face processing regions (Corbett et al., 2008; Humphreyset al., 2008; Figure 1a). Postmortem examinations of autistic brains reveal fewer neurons and less neuronal density in the layers of the fusiform gyrus compared to the brains of non-autistic individuals (Figure 1b). These differences were

not seen in the primary visual cortex or in the cerebral cortex as a whole (van Kooten et al., 2008). While this kind of microscopic analysis has been performed only in a few brains, these results suggest a cellular basis for the abnormalities in face perception found in autism. We must be careful, however, when ascribing cause and effect with these data. Do autistic people have poor face perception because they have fewer cells in fusiform cortex, or abnormal patterns of activity in these cells? Or are there fewer cells and reduced activity because they don’t look at faces? In a recent study, postmortem examination of brains found developmental changes in autistic brains that appeared to be the result of altered production, migration, and growth of neurons in multiple regions across the brain (Weigel et al., 2010). These widespread developmental changes may help explain the heterogeneity of the clinical autistic phenotype. It also supports the notion that poor face perception is the result of fewer cells, caused by abnormal development of neurons during gestation.

b

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FIGURE 1 Functional and structural neural correlates of autism. (a) Flattened cortical maps showing activation in response to faces, houses, and objects from typical developing individuals (left) and individuals with autism (right). The autistic individuals show a marked reduction in areas that are most activated by face stimuli. (b) Photomicrographs of 200 μm thick sections showing labeled neurons in cortical layers II (A, B) and III (C, D) of the fusiform gyrus. A control brain sample is on the left (A,C) and an autistic brain on the right (B,D). There is a reduction in the number of neurons in the autistic sample in Layer III.

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or is it best viewed as a general processor in which particular tasks (such as face perception) draw on machinery that can solve a range of problems? To investigate whether face recognition and other forms of object perception use distinct processing systems, three criteria are useful. 1. Does face perception involve physically distinct mechanisms? That is, are there particular regions of the brain or specialized cells that respond to faces? 2. Are the systems functionally and operationally independent? The logic of this criterion is essentially the same as that underlying the idea of double dissociations (see Chapter 3). 3. Do the two systems process information differently?

Table 6.1

Location of Lesion

Percentage of Totala

Bilateral (n = 46)

65

Temporal Parietal Occipital Left only (n = 4) Temporal

Do the processes of face recognition and non-facial object recognition involve physically distinct mechanisms? Although some patients show impairment only on face perception tests, more often, a patient’s performance on other object recognition tasks is also below normal. This result is, in itself, inconclusive regarding the existence of specialized brain mechanisms for face perception. Don’t forget that brain injury in humans is an uncontrolled experiment, in which multiple regions can be affected. With this caveat in mind, we can still evaluate whether patients with prosopagnosia have a common focus of lesions. In her classic book, Martha Farah performed a meta-analysis of the clinical and experimental literature on prosopagnosia (Farah, 2004). Table 6.1 summarizes the general location of the pathology in 71 cases where there was sufficient information about the location of the patients’ pathology. The most notable information is that the lesions were bilateral in 46 patients (65 %). For the remaining 25 patients (35 %) with unilateral lesions, the incidence was much higher for right-sided lesions than for left-sided lesions. For both bilateral and unilateral cases, the lesions generally involved occipital and temporal cortices. Given the messiness of human neuropsychology, it is important to look for converging evidence using the physiological tools of cognitive neuroscience. Neurophysiologists have recorded from the temporal lobes of primates to see if cells in this region respond specifically to faces. In one study (Baylis et al., 1985), recordings were made from cells in the superior temporal sulcus while presenting a monkey with stimuli like those at the top of Figure 6.25. Five of these stimuli (A–E) were faces: four of other monkeys, and one of an experimenter. The

61 9 91 6 75

Parietal

25

Occipital

50

Right only (n = 21)

Let’s see what evidence we have to answer these questions.

Regions of the Brain Involved in Face Recognition

Summary of Lesion Foci in Patients with Prosopagnosia

29

Temporal

67

Parietal

28

Occipital

95

a

Within each subcategory, the percentages indicate how the lesions were distributed across the temporal, parietal, and occipital lobes. The sum of these percentages is greater than 100% because many of the lesions spanned more than one lobe. Most of the patients had bilateral lesions.

other five stimuli (F–J) ranged in complexity but included the most prominent features in the facial stimuli. For example, the grating (image G) reflected the symmetry of faces, and the circle (image I) was similar to eyes. The results revealed that some cells were highly selective, responding only to the clear frontal profile of another monkey. Other cells raised their firing rate for all facial stimuli. Non-facial stimuli hardly activated the superior temporal sulcus cells. In fact, compared to spontaneous firing rates, activity decreased for some non-facial stimuli. The behavior of these cells closely resembles what would be expected of a grandmother cell. Research over the past two decades has confirmed that cells in at least two distinct regions of the temporal lobe are preferentially activated by faces: One region is in the superior temporal sulcus, the other is in the inferotemporal gyrus (Rolls, 1992). We cannot conclude that cells like these respond only to faces, since it is impossible to test all stimuli. Still, the degree of specificity is quite striking, as shown by a study that combined two neurophysiological methods in a novel manner. Monkeys were placed in an fMRI scanner and shown pictures of faces or objects. As expected, sectors of the superior temporal sulcus showed greater activation to the face stimuli; in fact, three distinct subregions in the superior temporal sulcus responded to faces (Tsao et al., 2006; Figure 6.26a). The researchers went on to record from individual neurons, using the imaging results to position the electrodes within one of the face-sensitive subregions of the superior

Processing Faces: Are Faces Special? | 249

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FIGURE 6.25 Identifying face cells in the superior temporal sulcus of the macaque monkey. The graphs (bottom row) show the responses of two cells to the 10 stimuli (labeled A–J). Both cells responded vigorously to many of the facial stimuli. Either there was no change in activity when the animal looked at the objects, or, in some cases, the cells were actually inhibited relative to baseline. The firingrate data are plotted as a change from baseline activity for that cell when no stimulus was presented.

temporal sulcus. In that subregion, 97 % of the neurons exhibited a strong preference for faces, showing strong responses to any face-containing stimulus and minimal responses to a wide range of other stimuli, such as body parts, food, or objects (Figure 6.26b, c). These data provide one of the most striking examples of stimulus specificity within a restricted part of the visual system. Various ideas have been considered to account for face selectivity. For example, facial stimuli might evoke emotional responses, and this property causes a cell to respond strongly to a face and not to other equally complex stimuli. The same cells, however, are not activated by other types of stimuli that produce a fear response in monkeys. A vigorous debate now taking place in the human fMRI literature concerns a dedicated face-perception area in the brain. Functional MRI is well suited to investigate this problem, because its spatial resolution can yield a much more precise image of face-specific areas than can be deduced from lesion studies. As in the monkey study just described, we can ask two questions by comparing conditions in which human participants

view different classes of stimuli. First, what neural regions show differential activation patterns when the participant is shown faces compared to the other stimulus conditions? Second, do these “face” regions also respond when the non-facial stimuli are presented? In one such study (G. McCarthy et al., 1997), participants were presented with pictures of faces together with pictures of either inanimate objects or random patterns (Figure 6.27). Compared to the BOLD response when viewing the random patterns, faces led to a stronger BOLD response along the ventral surface of the temporal lobe in the fusiform gyrus. When faces were alternated with inanimate objects, the response to faces in the fusiform gyrus of the right hemisphere remained significant. Many subsequent studies have shown that, relative to other classes of stimuli, faces produce activation in this region of the brain. Indeed, the consistency of this observation has led researchers to refer to this region as the fusiform face area, or FFA, a term that combines anatomy and function. The FFA is not the only region that shows a strong BOLD response to faces relative to other visual stimuli.

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M2 1

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Consistent with primate studies (discussed earlier), face regions have been identified in other parts of the temporal lobe, including the superior temporal sulcus. One hypothesis is that these different regions may show further specializations for processing certain types of information from faces. As noted earlier, people use face perception to identify individuals and to extract information about emotion and level of attention. Identifying people is best accomplished by using invariant features of facial structure (e.g., are the eyes broadly spaced?), and emotion identification requires processing dynamic features (e.g., is the mouth smiling?). One hypothesis is that the FFA is important for processing invariant facial properties, whereas the superior temporal sulcus is important for processing more dynamic features (Haxby et al., 2000). Indeed, the superior temporal

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FIGURE 6.26 Superior temporal sulcus (STS) regions that respond to faces. (a) Functional MRI activations during face perception in two macaque monkeys (M1 and M2). The white arrows indicate where subsequent neurophysiological recording was done (left STS in M1 and right STS in M2). (b) The activity of each of the cells recorded in the STS of M1 (left; 182 cells) and M2 (right; 138 cells) that responded to visual stimuli (face, bodies, fruits, gadgets, hands, or scrambled patterns). In these graphs, each row corresponds to a different cell, and each column corresponds to a different image category. (c) The average response size for each of the image categories across all cells. These cells were highly selective for face stimuli.

sulcus not only is responsive to facial expressions but also is activated during lip reading or when monitoring eye gaze. This distinction can be observed even in the BOLD response, when the faces are presented so quickly that people fail to perceive them consciously (Jiang & He, 2006). In that study, FFA was activated in response to all faces, independent of whether the faces depicted strong emotional expressions. The superior temporal sulcus, in contrast, responded only to the emotive faces (Figure 6.28). Electrophysiological methods also reveal a neural signature of face perception. Faces elicit a large negative evoked response in the EEG signal approximately 170 ms after stimulus onset. This response is known as the N170 response. A similar negative deflection is found for other classes of objects, such as cars, birds,

Processing Faces: Are Faces Special? | 251 Faces > Objects

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FIGURE 6.27 Isolating neural regions during face perception. (a) Bilateral activation in the fusiform gyrus was observed with fMRI when participants viewed collages of faces and random patterns compared with collages of only random patterns. Note that, following neuroradiological conventions, the right hemisphere is on the left. (b) In another fMRI study, participants viewed alternating blocks of stimuli. In one scanning run, the stimuli alternated between faces and objects; in another run, they alternated between intact and scrambled faces. The right-hand column shows the BOLD signal in the fusiform face area during the scanning run for the various stimuli. In each interval, the stimuli were drawn from the different sets—faces (F), objects (O), scrambled faces (S), or intact faces (I)—and these intervals were separated by short intervals of fixation only. The BOLD signal is much larger during intervals in which faces were presented.

and furniture, but the magnitude of the response is much larger for human faces (Carmel & Bentin, 2002; Figure 6.29). Interestingly, the stimuli need not be pictures of real human faces. The N170 response is also elicited when people view faces of apes or if the facial stimuli are crude, schematic line drawings (Sagiv & Bentin, 2001). Recording methods, either by single-cell physiology in the monkey or by fMRI and EEG recordings in people, are correlational in nature. Tests of causality generally require that the system be perturbed. For example, strokes can be considered a dramatic perturbation of normal brain function. More subtle methods involve transient perturbations. To this end, Hossein Esteky and colleagues at the Shaheed Beheshti University in Tehran used microstimulation in monkeys to test the causal contribution of inferior temporal cortex to face perception (Afraz et al., 2006). They used a set of fuzzy images that combined pictures of either flowers or faces, embedded in a backdrop of noise (i.e., random dots). A stimulus was shown on each trial, and the monkey had to judge if the stimulus contained a picture of a face or flower. Once the

animals had mastered the task, the team applied an electrical current, targeting a region within inferior temporal cortex that contained clusters of face-selective neurons. When presented with ambiguous stimuli, the monkeys showed a bias to report seeing a face (Figure 6.30). This effect was not seen when the microstimulation was targeted at nearby regions of the cortex. Although face stimuli are very good at producing activation in FFA, a rather heated debate has emerged in the literature on the question of whether the FFA is selectively activated for faces. An alternative hypothesis is that this region is recruited when people have to make fine perceptual discriminations among highly familiar stimuli. Advocates of this hypothesis point out that imaging studies comparing face and object recognition usually entail an important, if underemphasized, confound: the level of expertise. Consider the comparison of faces and flowers. Although neurologically healthy individuals are all experts in perceiving faces, the same is not true when it comes to perceiving flowers. Unless you are a botanist, you are unlikely to be an expert in recognizing flowers. In

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a Neutral faces Fearful faces

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addition, faces and flowers differ in terms of their social relevance: Face perception is essential to our social interactions. Whether or not we set out to remember someone’s face, we readily encode the features that distinguish one face from another. The same is probably not true for other classes of objects. Most of us are happy to recognize that a particular picture is of a pretty flower, perhaps even to note that it is a rose. But unless you are a rose enthusiast, you are not likely to recognize or encode the difference between a Dazzler and a Garibaldi, nor will you be able to recognize a particular individual rose that you have already seen. To address this confound, researchers have used imaging studies to determine if the FFA is activated in people who are experts at discriminating within specific classes of objects, such as cars or birds (Gauthier et al., 2000). The results are somewhat

FIGURE 6.28 fMRI responses of face-selective areas to both visible and invisible face images. (a) Two face-selective areas, the fusiform face area and the superior temporal sulcus, are depicted on the inflated right hemisphere of a representative observer. (b) When the stimuli were visible to the participants, the BOLD response was similar in both regions to the neutral and fearful faces. (c) When the stimuli were presented so briefly that the participants were unaware of them, the BOLD response in the STS was only evident for fearful faces.

mixed. Activation in fusiform cortex, which is made up of more than just the FFA, is in fact greater when people view objects for which they have some expertise. For example, car aficionados will respond more to cars than to birds. What’s more, if participants are trained to make fine discriminations between novel objects, the fusiform response increases as expertise develops (Gauthier et al., 1999). The categorization of objects by experts, however, activates a much broader region of ventral occipitotemporal cortex, extending beyond the FFA (Grill-Spector et al., 2004; Rhodes et al., 2004; Figure 6.31). Thus, it appears that both the face-specific and expertise hypotheses may hold some elements of truth. The ventral occipitotemporal cortex is involved in object recognition, and the engagement of this region, including FFA, increases with expertise (as measured by BOLD).

Processing Faces: Are Faces Special? | 253 Left mastoid

FIGURE 6.29 Electrophysiological response to faces: the N170 response. Participants viewed pictures of faces, birds, furniture, and cars and were instructed to press a button whenever they saw a picture of a car. The event-related potentials shown in the graphs are from the area surrounding the back of the skull at about the level of the ears (called the left and right mastoid). Note that the negative-going deflection in the waveform around 170 ms is much larger for the face stimuli compared to the other categories.

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processing systems. Can face and object perception be completely dissociated? Can a person have one without the other? As we have discovered, many case reports describe patients who have a selective disorder in face perception; they cannot recognize faces, but they have little problem recognizing other objects. Even so, this evidence does not mandate a specialized processor for faces. Perhaps the tests that assess face perception are more sensitive to the effects of brain damage than are the tests that evaluate object recognition.

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Are the processes of face recognition and non-facial object recognition functionally and operationally independent? Face perception appears to use distinct physical

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FIGURE 6.30 Effect of microstimulation of a face-selective region within inferior temporal cortex of a macaque monkey. (a) Random dots were added to make it hard to differentiate between a flower (−100% image) and a face (+100% image). The 0% stimulus is only random dots. The image was presented for 50 ms. On experimental trials, microstimulation started at the end of the stimulus interval and lasted for 50 ms. The monkey was very accurate whenever the image contained at least 50% of either the flower or face stimuli so testing was limited to stimuli between −50% and +50%. (b) Percentage of trials in which the monkey made an eye movement to indicate that the stimulus contained a face and not a flower. “Face” responses were more likely to occur on experimental trials compared to control trials.

254 | CHAPTER 6

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FIGURE 6.31 FFA activity is related to stimulus class and not expertise. A group of car aficionados viewed pictures of faces and cars that were presented very briefly (less than 50 ms). The stimuli were grouped based on whether the participant identified the specific face or car (green), correctly identified the category but failed to identify the person or car model (blue), or failed to identify the category (red). BOLD response in FFA varied with performance for the faces, with strongest response to stimuli correctly identified. The BOLD response was weak and unrelated to performance to the cars, even for these experts.

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Striking cases have emerged, however, of the reverse situation—patients with severe object recognition problems but no evidence of prosopagnosia. Work with C.K., the patient described earlier in the section on integrative agnosia (see Figure 6.19), provides a particularly striking example. Take a look at Figure 6.32, a still life produced by the quirky 16th-century Italian painter Giuseppe Arcimboldo. When shown this picture, C.K was stumped. He reported a mishmash of colors and shapes, failing to recognize either the individual vegetables or the bowl. But when the painting was turned upside down, C.K. immediately perceived the face. When compared to patients with prosopagnosia, individuals like C.K. provide a double dissociation in support of the hypothesis that the brain has functionally different systems for face and object recognition. A different concern arises, however, when we consider the kinds of tasks typically used to assess face and object perception. In one important respect, face perception tests are qualitatively different from tests that evaluate the recognition of common objects. The stimuli for assessing face perception are all from the same category: faces. Study participants may be asked to decide whether two faces are the same or different, or

they may be asked to identify specific individuals. When patients with visual agnosia are tested on object perception, the stimuli cover a much broader range. Here participants are asked to 4 discriminate chairs from tables, or to identify common objects such as clocks and telephones. Face perception tasks involve within-category discriminations; object perception tasks typically involve between-category discriminations. Perhaps the deficits seen in prosopagnosia patients reflect a more general problem in perceiving the subtle differences that distinguish the members of a common category. The patient literature fails to support this hypothesis, however. For example, a man who became a sheep farmer (W.J.) after developing prosopagnosia was tested on a set of within-category identification tasks: one involving people, the other involving sheep (McNeil & Warrington, 1993). In a test involving the faces of people familiar to him, W.J. performed at the level of chance. In a test involving the faces of sheep familiar to him, by contrast, W.J. was able to pick out photographs of sheep from his own flock. In a second experiment, W.J.’s recognition memory was tested. After viewing a set of pictures of sheep or human faces, W.J. was shown these same stimuli mixed with new photographs. W.J.’s performance in recognizing the sheep faces was higher than that of other control participants, including other sheep farmers. For human faces, though, W.J.’s performance was at the level of chance, whereas the control participants’ performances were close to perfect. This result suggests that for recognizing human faces, we use a particular mental pattern or set of cues. W.J. was no longer able to use the pattern, but that didn’t matter when it came to sheep faces. Perhaps he was superior at recognizing sheep faces because he did not have such a pattern interfering with his processing of sheep faces. We will return to this idea in a bit.

Processing Faces: Are Faces Special? | 255

Faces Are Processed in a Holistic Manner Do the mechanisms of face recognition and non-facial object recognition process information differently? To address this question, let’s contrast prosopagnosia with another subtype of visual agnosia—acquired alexia. Patients with acquired alexia following a stroke or head trauma have reading problems. Although they understand spoken speech and can speak normally, reading is painstakingly difficult. Errors usually reflect visual confusions. The word ball may be misread as doll, or bail as talk. Like prosopagnosia, alexia is a within-category deficit; that is, the affected person fails to discriminate between items that are very similar. In healthy individuals, fMRI scans reveal very different patterns of activation during word perception from those observed in studies of face perception. Letter strings do not activate the FFA; rather, the activation is centered more dorsally (Figure 6.33) and is most prominent in the left hemisphere, independent of whether the words are presented in the left or right visual field (L. Cohen et al., 2000). Moreover, the magnitude of the activation increases when the letters form familiar words (L. Cohen et al., 2002). Though this area may be thought of as FIGURE 6.32 What is this a painting of? The Arcimboldo painting that stumped C.K. when he viewed it right specialized for reading, an evolutionary argument akin side up but became immediately recognizable as a different form to what has been offered for face perception does not when he turned it upside down. To see what C.K. saw, keep an eye seem tenable. Learning to read is a challenging process on the turnip when you turn the image upside down. that is part of our recent cultural history. Even so, computations performed by this Stimulated hemifield region of the brain appear to Left Right be well suited for developing the representations required for reading. Left fusiform Prosopagnosia and alexia gyrus rarely occur in isolation. Put another way, both types of patients usually have problems with other types of object recognition. Importantly, the dissociation between prosopagnosia and acquired V4 alexia becomes evident when we consider the patterns of correlation among three types of agnosia: for faces, for objects, and for words. Table FIGURE 6.33 Activation of visual word-form area in the left hemisphere during reading compared torest. 6.2 lists the pattern of coIn separate blocks of trials, words were presented in either the left visual field or right visual field. occurrence from one metaIndependent of the side of stimulus presentation, words produced an increase in the BOLD response analysis of visual associative in the left fusiform gyrus (green circled region in top row), an area referred to as the visual word form. agnosia (Farah, 1990). PaIn contrast, activation in V4 (blue and red circles in bottom row) was always contralateral to the side of tients who are impaired in stimulation. The black bars on the lateral views of the brain indicate the anterior-posterior position of recognizing all three types of the coronal slices shown on the left. V4 is more posterior to the visual word form area.

256 | CHAPTER 6

Table 6.2

Object Recognition

Patterns of Co-occurrence of Prosopagnosia, Object Agnosia, and Alexia

Pattern

Number of Patients

Deficits in all three

21 Selective deficits

Face and objects

14

Words and objects

15

Faces and words

1 (possibly)

Faces alone

35

Words alone

Many described in literature

Objects only

1 (possibly)

materials likely have extensive lesions that affect multiple processes. The more interesting cases are the patients with impairments limited to just two of the three categories. A patient could be prosopagnosic and object agnosic without being alexic. Or a patient could be object agnosic and alexic without being prosopagnosic. But only one patient was reported to have prosopagnosia and alexia with normal object perception, and even in this case, the report was unclear. Another way to view these results is to consider that agnosia for objects never occurs alone; it is always accompanied by a deficit in either word or face perception, or both. Because patients with deficits in object perception also have a problem with one of the other types of stimuli, it might be tempting to conclude that object recognition involves two independent processes. It would not be parsimonious to postulate three processing subsystems. If that were the case, we would expect to find three sets of patients: those with word perception deficits, those with face perception deficits, and those with object perception deficits. Given that the neuropsychological dissociations suggest two systems for object recognition, we can now examine the third criterion for evaluating whether face perception depends on a processing system distinct from the one for other forms of object perception: Do we process information in a unique way when attempting to recognize faces? That is, are there differences in how information is represented when we recognize faces in comparison to when we recognize common objects and words? To answer these questions, we need to return to the computational issues surrounding the perception of facial and non-facial stimuli. Face perception appears to be unique in one special way—whereas object recognition decomposes a stimulus into its parts, face perception is more holistic. We recognize an individual according to the facial

configuration, the sum of the parts, not by his or her idiosyncratic nose or eyes or chin structure. By this hypothesis, if patients with prosopagnosia show a selective deficit in one class of stimuli—faces—it is because they are unable to form the holistic representation necessary for face perception. Research with healthy people reinforces the notion that face perception requires a representation that is not simply a concatenation of individual parts. In one study, participants were asked to recognize line drawings of faces and houses (Tanaka & Farah, 1993). Each stimulus was constructed of limited parts. For faces, the parts were eyes, nose, and mouth; for houses, the parts were doors, living room windows, and bedroom windows. In a study phase, participants saw a name and either a face or a house (Figure 6.34a, upper panel). For the face, participants were instructed to associate the name with the face; for example, “Larry had hooded eyes, a large nose, and full lips.” For the house, they were instructed to learn the name of the person who lived in the house; for example, “Larry lived in a house with an arched door, a red brick chimney, and an upstairs bedroom window.” After this learning period, participants were given a recognition memory test (Figure 6.34a, lower panel). The critical manipulation was whether the probe item was presented in isolation or in context, embedded in the whole object. For example, when asked whether the stimulus matched Larry’s nose, the nose was presented either by itself or in the context of Larry’s eyes and mouth. As predicted, house perception did not depend on whether the test items were presented in isolation or as an entire object, but face perception did (Figure 6.34b). Participants were much better at identifying an individual facial feature of a person when that feature was shown in conjunction with other parts of the person’s face. The idea that faces are generally processed holistically can account for an interesting phenomenon that occurs when looking at inverted faces. Take a look at the faces in Figure 6.35. Who is it? Is it the same person or not? Now turn the book upside down. Shocking, eh? One of the images has been “Thatcherized,” so called because it was first done to an image of the former English prime minister, Margaret Thatcher (P. Thompson, 1980). For this face, we fail to note that the eyes and mouth have been left in their right-side-up orientation. We tend to see the two faces as identical, largely because the overall configuration of the stimuli is so similar. Rhesus monkeys show the same reaction as humans to distorted, inverted faces. They don’t notice the change in features until they are presented right side up (Adachi et al., 2009). This evidence suggests that

Processing Faces: Are Faces Special? | 257 Study phase This is Larry’s house.

This is Larry.

Test phase

FIGURE 6.35 Who is this person? Is there anything unusual about the picture? Recognition can be quite difficult when faces are viewed upside down. Even more surprising, we fail to note a severe distortion in the upper image created by inversion of the eyes and mouth—something that is immediately apparent when the image is viewed right side up. Theperson is Margaret Thatcher.

Is this Larry’s nose?

Part condition Whole condition Is this Larry’s door?

Part condition

Whole condition

Percentage correct

a

80 Isolated-part condition 70 Whole-object condition

60

Faces

Houses

perception reflects the operation of two distinct representational systems. The relative contribution of the analysis-by-parts and holistic systems will depend on the task (Figure 6.36). Face perception is at one extreme. Here, the critical information requires a holistic representation to capture the configuration of the defining parts. For these stimuli, discerning the parts is of little importance. Consider how hard it is to notice that a casual acquaintance has shaved his mustache. Rather, recognition requires that we perceive a familiar arrangement of the parts. Faces are special, in the sense that the representation derived from an analysis by parts is not sufficient. Words represent another special class of objects, but at the other extreme. Reading requires that the letter strings be successfully decomposed into their constituent parts. We benefit little from noting general features Faces

Objects

b FIGURE 6.34 Facial features are poorly recognized in isolation. (a) In the study phase, participants learned the names that correspond with a set of faces and houses. During the recognition test, participants were presented with a face, a house, or a single feature from the face or house. They were asked if a particular feature belonged to an individual. (b) When presented with the entire face, participants were much better at identifying the facial features. Recognition of the house features was the same in both conditions. Holistic analysis

a face perception mechanism may have evolved in an ancestor common to humans and rhesus monkeys more than 30 million years ago. When viewed in this way, the question of whether face perception is special changes in a subtle yet important way. Farah’s model emphasizes that higher-level

Words

qwertyurcz rgklzobrus zxascdftqv owxskateln mpqrdambg tlewqnukca ertuyesmlr

Analysis by parts

FIGURE 6.36 Farah’s two-process model for object recognition. Recognition can be based on two forms of analysis: holistic analysis and analysis by parts. The contributions of these two systems vary for different classes of stimuli. Analysis by parts is essential for reading and is central for recognizing objects. A unique aspect of face recognition is its dependence on holistic analysis. Holistic analysis also contributes to object recognition.

258 | CHAPTER 6

Object Recognition

such as word length or handwriting. To differentiate one word from another, we have to recognize the individual letters. In terms of recognition, objects fall somewhere between the two extremes of words and faces. Defining features such as the number pad and receiver can identify a telephone, but recognition is also possible when we perceive the overall shape of this familiar object. If either the analytic or the holistic system is damaged, object recognition may still be possible through operation of the intact system. But performance is likely to be suboptimal. Thus, agnosia for objects can occur with either alexia or prosopagnosia. In normal perception, both holistic and part-based systems are operating to produce fast, reliable recognition. These two processing systems converge on a common percept, although how efficiently they do so will vary for different classes of stimuli. Face perception is primarily based on a holistic analysis of the stimulus. Nonetheless, we are often able to recognize someone by his distinctive nose or eyes. Similarly, with expertise, we may recognize words in a holistic manner, with little evidence of a detailed analysis of the parts. The distinction between analytic processing and holistic processing has also been important in theories of hemispheric specialization; the core idea is that the left hemisphere is more efficient at analytic processing and the right hemisphere is more efficient at holistic processing (see Chapter 4). For our present purposes, it is useful to note that alexia and prosopagnosia are in accord with this lateralization hypothesis: lesions to the right hemisphere are associated with prosopagnosia and those to the left with alexia. As we saw in Chapter 4, an important principle in cognitive neuroscience is that parallel systems (e.g., the two hemispheres) may afford different snapshots of the world, and the end result is an efficient way to represent different types of information. A holistic system supports and may even have evolved for efficient face perception; an analytic system allows us to acquire fine perceptual skills like reading.

consistently engaged when the control stimuli contained pictures of scenes such as landscapes. This region was not activated by face stimuli or by pictures of individual objects. Subsequent experiments confirmed this pattern, leading to the name parahippocampal place area, or PPA. The BOLD response in this region was especially pronounced when people were required to make judgments about spatial properties or relations, such as, is an image of an outdoor or indoor scene? or, is the house at the base of the mountain? Reasonable evolutionary arguments can be made concerning why the brain might have dedicated regions devoted to recognizing faces or places, but not to making other types of distinctions. Individuals who could distinguish one type of apple from another would be unlikely to have a strong adaptive advantage (although being able to perceive color differences that cue whether a particular piece of fruit is ripe would be important). Our ancestors who could remember where to find the ripe fruit, however, would have a great advantage over their more forgetful peers. Interestingly, people with lesions to the parahippocampus become disoriented in new environments (Aguirre & D’Esposito, 1999; Habib & Sirigu, 1987). Other studies suggest the visual cortex may have a region that is especially important for recognizing parts of the body (Figure 6.37; Downing et al., 2001). This area, at the border of the occipital and temporal cortices, is referred to as the extrastriate body area (EBA). Another region, adjacent to and partially overlapping the FFA, shows a similar preference for body parts and has been called the fusiform body area (FBA; Schwarzlose et al., 2005).

Does the Visual System Contain Other Category-Specific Systems? If we accept that evolutionary pressures have led to the development of a specialized system for face perception, a natural question is whether additional specialized systems exist for other biologically important classes of stimuli. In their investigations of the FFA, Russell Epstein and Nancy Kanwisher (1998) used a large set of control stimuli that were not faces. When they analyzed the results, they were struck by a serendipitous finding. One region of the ventral pathway, the parahippocampus, was

FIGURE 6.37 Locations of the EBA and FBA. Right-hemisphere cortical surface of an “inflated brain” in one individual identifying the EBA, FBA, and face-sensitive regions. Regions responded selectively to bodies or faces versus tools. Note that two regions respond to faces, the OFA and FFA. (EBA=extrastriate body area; OFA = occipital face area; FFA = fusiform face area; FBA = fusiform body area.)

Processing Faces: Are Faces Special? | 259 Functional MRI has proven to be a powerful tool for exploring category-specific preferences across the visual cortex. Some regions, such as FFA, PPA, and EBA, show strong preferences for particular categories. Other areas respond similarly to many different categories of visual stimuli. As we’ve already seen, functional hypotheses have been proposed to explain why some degree of specialization may exist, at least for stimuli of long-standing biological importance. Still, it is necessary to confirm that these regions are, in fact, important for specific types of perceptual judgments. Brad Duchaine and his colleagues used transcranial magnetic stimulation (TMS) to provide one such test by seeking to disrupt activity in three different regions that had been shown to exhibit category specificity (Pitcher et al.,

Occipital face area (OFA)

2009). The study participants performed a series of discrimination tasks that involved judgments about faces, bodies, and objects. In separate blocks of trials, the TMS coil was positioned over the right occipital face area (rOFA), the right extrastriate body area (rEBA), and the right lateral occipital area (rLO; Figure 6.38a). (The FFA was not used because, given its medial position, it is inaccessible to TMS.) The results showed a neat triple dissociation (Figure 6.38b–d). When TMS was applied over the rOFA, participants had problems discriminating faces, but not objects or bodies. When it was applied over the rEBA, the result was impaired discrimination of bodies, but not faces or objects. Finally, as you have probably guessed, when TMS was

Lateral occipital area (LO)

Extrastriate body area (EBA)

a

Faces and Bodies

LO EBA No TMS

3

2.5

2.5

2

2

2

1.5

1.5

1.5

d1

2.5

1

1

1

0.5

0.5

0.5

0 b

3

d1

d1

3

Objects and Bodies

OFA LO No TMS

Faces

Objects

0 c

Objects

Bodies

0 d

FIGURE 6.38 Triple dissociation of faces, bodies, and objects. (a) TMS target sites based on fMRI studies identifying regions in the right hemisphere sensitive to faces (OFA), objects (LO), and bodies (EBA). (b–d) In each panel, performance on two tasks was compared when TMS was applied in separate blocks to two of the stimulation sites, as well as in a control condition (no TMS). The dependent variable in each graph is d’, a measure of perceptual performance (high values = better performance). Face performance was disrupted by TMS over OFA. Object perception was disrupted by TMS over LO. Body perception was disrupted by TMS over EBA.

rOFA rEBA No TMS

d1

Faces and Objects

Faces

Bodies

260 | CHAPTER 6

Object Recognition

applied over the rLO, the participants had difficulty picking out objects, but not faces or bodies (Pitcher et al., 2009). The latter result is especially interesting because the perception of faces and bodies was not disrupted. Regions that are involved in categoryindependent object recognition processes must be downstream from rLO. The question remains, what are the causes of such category specificity within the organization of the visual system? Has it been shaped by visual experience,

or are we born with it? Put another way, do category preferences depend on visual experience that defines dimensions of similarity, or by dimensions of similarity that cannot be reduced to visual experience? This issue was addressed in our discussion of the computational model proposed by Farah and McClelland to account for the difference between living and nonliving objects. That model emphasized functional differences between these two categories, but the fMRI data has also shown some degree of anatomical segregation. Inanimate

Left lateral occipital region

BOLD response

Sighted: auditory task

Congenitally blind auditory task

0.2 0.15 0.1 0.05 0 –0.05 –0.1 –0.15 –0.2

2

Sighted: picture viewing

1.5 1 0.5 0

Non-living Living

a Left medial ventral region

BOLD response

Sighted: auditory task

Congenitally blind auditory task

0.2 0.15 0.1 0.05 0 –0.05 –0.1 –0.15 –0.2

2

Sighted: picture viewing

1.5 1 0.5 0

Right medial ventral region

BOLD response

Sighted: auditory task

b

0.2 0.15 0.1 0.05 0 –0.05 –0.1 –0.15 –0.2

Congenitally blind auditory task

2

Sighted: picture viewing

1.5 1 0.5 0

FIGURE 6.39 BOLD response in three regions of interest (ROIs) defined in scans from sighted individuals. Sighted participants viewed the stimuli or listened to words naming the stimuli. Congenitally blind participants listened to the words. (a) The blind participants show stronger response to animals compared to objects in left lateral occipital ROI, similar to that observed in sighted individuals when viewing the pictures. (b) Medial ventral ROIs show preference for the objects in both groups. Note that all three ROIs are deactivated when sighted participants listened to thewords.

Mind Reading | 261 objects produce stronger activation in the medial regions of the ventral stream (the medial fusiform gyrus, lingual gyrus, and parahippocampal cortex), whereas animate objects produce stronger activation in more lateral regions (the lateral fusiform gyrus and the inferior temporal gyrus). Brian Mahon and his colleagues (2009) investigated whether congenitally blind adults, who obviously have had no visual experience, would show a similar categorical organization in their visual areas. “Visual cortex” in the congenitally blind is recruited during verbal processing (e.g., Amedi et al., 2004). Based on this knowledge, Mahon asked if a medial–lateral distinction would be apparent when blind participants had to make judgments about the sizes of objects that were presented to them auditorily. In each trial, the participants heard a word, such as “squirrel.” Then they were presented with five additional words of the same conceptual category, for instance, piglet, rabbit, skunk, cat, and moose (all animals), and asked to indicate if any of the items were of a vastly different size (in this example, the moose). The point of the judgment task was to ensure that the participants had to think about each stimulus. Sighted participants performed the same task and were also tested with visual images. As it turns out, the regions that exhibited category preferences during the auditory task were the same in both the sighted and nonsighted groups (Figure 6.39). Moreover, these regions showed a similar difference to animate and inanimate objects when the sighted participants repeated the task, but this time with pictures. Thus, visual experience is not necessary for category specificity to develop within the organization of the ventral stream. The difference between animate and inanimate objects must reflect something more fundamental than what can be provided by visual experience.

Analytic processing is a form of perceptual analysis that emphasizes the component parts of an object, a mode of processing that is important for reading.

Holistic processing is a form of perceptual analysis that emphasizes the overall shape of an object, a mode of processing that is important for face perception.

Just as the FFA is specialized for processing faces, the parahippocampal place area (PPA) is specialized for processing information about spatial relations or for classifying objects based on spatial properties (e.g., anindoor vs. outdoor scene).

Likewise, the extrastriate body area (EBA) and the fusiform body area (FBA) have been identified as more active when body parts are viewed.

TAKE-HOME MESSAGES

Encoding and Decoding Brain Signals

Category-specific deficits are deficits of object recognition that are restricted to certain classes of objects.

Prosopagnosia is an inability to recognize faces that cannot be attributed to deterioration in intellectual function.

Acquired alexia is characterized by reading problems that occur after a patient has a stroke or head trauma.

Neurons in various areas of the monkey brain show selectivity for face stimuli.

Similarly, specificity is observed in fMRI studies, including an area in the fusiform gyrus of the temporal lobe, the fusiform face area, or FFA.

Mind Reading We have seen various ways in which scientists have explored specialization within the visual cortex. In Chapter 5, emphasis was on how basic sensory properties such as shape, color, and motion are processed. In this chapter, we have looked at more complex properties such as animacy, faces, places, and body parts. The basic research strategy has been to manipulate the input and then measure the response to the different types of inputs. For example, FFA is more responsive to face stimuli than non-face stimuli. These observations have led scientists to realize that it should, at least in principle, be possible to analyze the system in the opposite direction (Figure 6.40). That is, we should be able to look at someone’s brain activity and infer what the person is currently seeing (or has recently seen, assuming our measurements are delayed), a form of mind reading. This idea is referred to as decoding.

As the name implies, decoding is like breaking a secret code. The brain activity, or whatever measurement we are using, provides the coded message, and the challenge is to decipher that message and infer what is being represented. In other words, we could read a person’s mind, making inferences about what they are currently seeing or thinking, even if we don’t have direct access to that input. All this may sound like science fiction, but as we’ll see, over the past decade scientists have made tremendous advances in mind reading. While consid-

262 | CHAPTER 6

Object Recognition

Decode

Encode

Observe

Encoding

Predict

Feature Space

BOLD Response

Decoding

Stimulus

BOLD Responses

Stimulus

FIGURE 6.40 Encoding and decoding neural activity. Encoding refers to the problem of how stimulus features are represented in neural activity. The image is processed by the sensory system and the scientist wants to predict the resulting BOLD activity. Decoding (or mind reading) refers to the problem of predicting the stimulus that is being viewed when a particular brain state is observed. In fMRI decoding, the BOLD activity is used to predict the stimulus being observed by the participant. Successful encoding and decoding require having an accurate hypothesis of how information is represented in the brain (feature space).

ering the computational challenges involved, we must keep two key issues in mind. First, our ability to decode will be limited by the resolution of our measurement system. Single-cell neurophysiology, if we have identified the “right” cell, might be useful for telling us if the person is looking at Halle Berry. In fact, we might even be able to detect when the person is daydreaming about Halle Berry if our cell were as selective as suggested in Figure 3.21. Currently, decoding methods allow us to sample only a small number of cells. Nonetheless, in some future time, scientists may develop methods that allow the simultaneous measurement of thousands, or even millions, of cells; perhaps the entire ventral pathway. Until then, we have to rely on much cruder tools such as EEG and fMRI. EEG is rapid, so it provides excellent temporal resolution. But the number of recording channels is limited (current systems generally have a maximum of 256 channels), and each channel integrates information over large regions of the cortex, and thus, limits spatial resolution. Although fMRI is slow

and provides only an indirect measure of neural activity, it provides much better spatial resolution than EEG does. With fMRI, we can image the whole brain and simultaneously take measurements in hundreds of thousands of voxels. Using more focused scanning protocols can reduce the size of the voxels, thus providing better spatial resolution. Of course, mind reading is not going to be all that useful if the person has to maintain the same thought for, say, 10 or 20 seconds before we get a good read on their thoughts. Perception is a rapid, fluid process. A good mind-reading system should be able to operate at similar speeds. The second issue is that our ability to decode mental states is limited by our models of how the brain encodes information. Developing good hypotheses about the types of information that are represented in different cortical areas will help us make inferences when we attempt to build a brain decoder. To take an extreme example, if we didn’t know that the occipital lobe was responsive to visual input, it would be very hard to look

Mind Reading | 263 at the activity in the occipital lobe and make inferences about what the person was currently doing. Similarly, having a good model of what different regions represent—for example, that a high level of activity in V5 is correlated with motion perception—can be a powerful constraint on the predictions we make of what the person is seeing. Early efforts at mind reading were inspired by the discovery of category-specific visual areas. We saw in the previous section that the BOLD signals in FFA and PPA vary as a function of whether the person is looking at faces or places. This information provides a simple encoding model. Kathleen O’Craven and Nancy Kanwisher at MIT found that this distinction could be used to constrain a decoding model (O’Craven & Kanwisher, 2000). People were placed in an fMRI scanner and asked to imagine either a famous face or a familiar place. Using just the resulting BOLD activity measured in FFA and PPA, it was possible to predict if the person was looking at a face or place on about 85 % of the trials (Figure 6.41). What’s impressive about this result is that even though the BOLD signal in each area is very small for a single event, especially when there is no overt visual stimulus, the observer, who had to choose either “face” or “place,” almost always got the right answer. Could this analysis be done by a machine and in a much shorter amount of time? Geraint Rees and his colleagues at University College London reasoned that more parts of the brain than just the PPA and FFA likely contributed to the mental event. Thus, they constructed a decoder that took the full spatial pattern of brain activity into account by simultaneously measuring many locations within the brain, including the early visual areas (Haynes & Rees, 2006). Using a single brain

image and data collected from the participant over just 2 seconds, their pattern-based decoder extracted considerably more information and had a prediction accuracy of 80 %.

Statistical Pattern Recognition Impressive, yes; but also rather crude. After all, the decoder wasn’t presented with a very challenging mindreading problem. It only had to decide between two very different categories. What’s more, the predictor was given the two categories to choose from. That binary decision process is nothing like how random thoughts flit in and out of our minds. Moreover, discrimination was only at the categorical level. A much more challenging problem would be to make distinctions within a category. There is a big difference between Santa Claus and Marilyn Monroe or Sioux City and Tahiti. Can we do better, even given the limitations of fMRI? We can. To do it, we need a much more sophisticated encoding model. We need one that gives us more than just a description of how information is represented acr