Neuroscience of Cognitive Development E-Book

Contents

Preface

Acknowledgments

Introduction: Why Should Developmental Psychologists Be Interested in the Brain?

Chapter 1: Brain Development and Neural Plasticity

Brain Development

Stages of Brain Development

Summary

Chapter 2: Neural Plasticity

Developmental Plasticity

Adult Plasticity

Chapter 3: Methods of Cognitive Neuroscience

Lesion Method

Electrophysiological Procedures

Metabolic Procedures (fMRI)

Optical Imaging

Magnetic Encephalography

Summary

Chapter 4: The Development of Speech and Language

The Neural Bases of Speech and Language Development

Neural Bases of Speech Processing and Speech Perception

Summary

Chapter 5: The Development of Declarative (or Explicit) Memory

Memory Systems

The Development of Memory Systems—Some Background

Disorders of Memory

Chapter 6: The Development of Nondeclarative (or Implicit) Memory

Visual Priming

Implicit Sequence Learning

Conditioning or Associative Learning

Chapter 7: The Development of Spatial Cognition

Mental Rotation

Spatial Pattern Processing

Spatial Navigation

Chapter 8: The Development of Object Recognition

Occipitotemporal Cortex

Amygdala

Role of Experience

Is There a Visuospatial Module?

Chapter 9: The Development of Social Cognition

Processing Social Information in the Face

Facial Expressions of Emotion

Eye Gaze

Neural Bases

Occipitotemporal Regions

Superior Temporal Sulcus

Amygdala

Frontal Cortex

Other Brain Areas

Role of Experience

Summary

Theory of Mind

Conclusions

Chapter 10: The Development of Higher Cognitive (Executive) Functions

Domains of Executive Function

Visuospatial Working Memory

Visuospatial Recognition and Recall Memory

Working Memory Redoux

Inhibitory Control

Attentional Control

Chapter 11: The Development of Attention

Alerting, Vigilance, or Arousal

Orienting

Conclusion

Chapter 12: The Future of Developmental Cognitive Neuroscience

References

Index

Copyright © 2006 by John Wiley & Sons, Inc. All rights reserved.

Published by John Wiley & Sons, Inc., Hoboken, New Jersey.

Published simultaneously in Canada.

Portions of this book originally appeared in W. Damon (Series Editor) and R. Lerner, D. Kuhn, and R. Siegler (Volume Editors), Handbook of Child Psychology: Vol. 2. Cognitive, Perception, and Language, sixth edition, Hoboken, NJ: Wiley.

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Library of Congress Cataloging-in-Publication Data:

Nelson, Charles A. (Charles Alexander)

Neuroscience of cognitive development: the role of experience and the developing brain / by Charles A. Nelson, Michelle de Haan, Kathleen M. Thomas.

p. cm.

ISBN-13: 978-0-471-74586-0 (cloth)

ISBN-10: 0-471-74586-3 (cloth)

1. Cognitive neuroscience. 2. Developmental psychology. 3. Experience.

[DNLM: 1. Cognition—physiology. 2. Brain—growth & development. 3. Child Development—physiology. 4. Adolescent Development—physiology. WS 105.5.C7 N425n 2006] I. De Haan, Michelle, 1969– II. Thomas, Kathleen M., 1970– III. Title.

QP360.5.N45 2006

612.8′233—dc22

2005021552

Preface

Our goal in writing this book is to introduce the reader to what is currently known about the neural bases of cognitive development. We begin by introducing a number of reasons why developmental psychologists might be interested in the neural bases of behavior (with particular reference to cognitive development). Having established the value of viewing child development through the lens of the developmental neurosciences, we provide an overview of brain development. This is followed by a discussion of how experience influences the developing—and when appropriate, developed—brain. Within this discussion on experience-dependent changes in brain development, we briefly touch on two issues we consider to be essential for all developmental psychologists: whether the mechanisms that underlie developmental plasticity differ from those that underlie adult plasticity, and more fundamentally, what distinguishes plasticity from development.

With this basic neuroscience background behind us, we next turn our attention to how one examines the neural bases of cognitive development—this will essentially be a tutorial on the methods employed by those working in developmental cognitive neuroscience. We begin this section with a brief historical tour, then move the discussion to behavioral (i.e., neuropsychological), anatomic (e.g., structural MRI), metabolic (e.g., functional MRI, functional Near Infrared Spectroscopy), and electrophysiological methods (e.g., event-related potentials).

Once we have concluded our discussion of methods, we turn our attention to specific content areas, limiting ourselves to domains in which there is a corpus of knowledge about the neural underpinnings of cognitive development. We include discussions of declarative and nondeclarative memory and learning, spatial cognition, object recognition, social cognition, speech and language development, executive functions, and attention. We conclude the book with a brief discussion of the future of developmental cognitive neuroscience.

Acknowledgments

We thank Robert Shannon for assistance in developing many of the figures for this book, Eric Hart and Trisha Dasgupta for editorial assistance, and the members of the Developmental Cognitive Neuroscience Laboratory, who offered valuable feedback on an earlier version of this book.

Introduction

Why Should Developmental Psychologists Be Interested in the Brain?

Historical Background

Prior to the ascendancy of Piagetian theory, the field of cognitive development was dominated by behaviorism (for discussion, see Goldman-Rakic, 1987; Nelson & Bloom, 1997). Behaviorism eschewed the nonobservable, and therefore, the study of the neural bases of behavior, for the simple reason that neural processes could not be observed. (With the benefit of hindsight, this view always struck us as faulty logic because it failed to recognize that behavior was a product of physiology, and without understanding what caused behavior, the interpretation of the behavior itself would be incomplete.) Through the 1950s and 1960s, Piagetian theory gradually came to replace behaviorism as the dominant theory of cognitive development. However, despite a background in biology, Piaget and, subsequently, his followers primarily concerned themselves with developing a richly detailed cognitive architecture of the mind—albeit a brainless mind. We do not mean this in the pejorative sense, but rather, to reflect that the zeitgeist of the time was to develop elegant models of cognitive structures, with little regard for (a) whether such structures were biologically plausible, or (b) the neurobiological underpinnings of such structures. (And, of course, at this time there was no way to observe the living child’s brain directly.) Throughout the late 1970s and into the last decade of the twentieth century, neo- and non-Piagetian approaches came into favor. Curiously, a prominent theme of a number of investigators writing during this time was that of nativism. We say curiously because inherent in nativism is the notion of biological determinism, yet those touting a nativist perspective rarely if ever grounded their models and data in any kind of biological reality. It was not until the mid-1990s that neurobiology began to be inserted into a discussion of cognitive development, as reflected, for example, in Mark Johnson’s eloquent contribution to the fifth edition of the Handbook of Child Psychology (Johnson, 1998). This perspective has become more commonplace, although the field of developmental cognitive neuroscience is still in its infancy. (For recent overviews of this field generally, see de Haan & Johnson, 2003, and Nelson & Luciana, 2001.) Moreover, our personal experience is that it is still not clear to many developmental psychologists why they should be interested in the brain. This is the topic to which we first direct our attention.

Our understanding of cognitive development will be improved as the mechanisms that underlie development are elucidated. This, in turn, should permit us to move beyond the descriptive, black box level to the level at which the actual cellular, physiologic, and eventually, genetic machinery will be understood—that is, the mechanisms that underlie development.

For example, a number of distinguished cognitive developmentalists and cognitive theorists have proposed or at least implied that elements of number concept (Wynn, 1992; Wynn, Bloom, & Chiang, 2002), object permanence (Baillargeon, 1987; Baillargeon, Spelke, & Wasserman, 1985; Spelke, 2000), and perhaps face recognition (Farah, Rabinowitz, Quinn, & Liu, 2000) reflect what we refer to as experience-independent functions; that is, they reflect in-born “traits” (presumably coded in the genome) that require little if any experience in order to emerge. We see several problems with this perspective. First, these arguments seem biologically implausible. Such sophisticated cognitive abilities, if they were coded in the genome, would surely involve polygenic traits rather than reflect the action of a single gene. Given that we now know the human genome consists of approximately 30,000 genes, it seems highly unlikely that we could spare the genes to code for number concept, object permanence, or face recognition; after all, our existing complement of genes must be involved in a myriad of other events of more basic importance than subserving these aspects of cognitive development (such as the general operation of the body as a whole).

A second concern about this nativist perspective is that it is not particularly developmental. To say that something is “innate” essentially closes the door to any discussion of mechanism. More problematic is that genes do not “cause” behaviors; rather, genes express proteins that in turn work their magic through the brain. And, it seems unlikely that behaviors that are not absolutely essential to survival (of the species, not the individual) have been coded for in the genome, given the limited number of genes that are known to exist in the genome. Far more likely is that these behaviors are subserved by discrete or distributed neural circuits in the brain, and, these circuits, in turn, likely vary in the extent to which they depend on experience or activity for their subsequent elaboration (a topic we discuss in detail in Chapter 3).

Collectively, we wish to make three points. First, the value added by thinking of behavior in the context of neurobiology is that doing so provides a form of biological plausibility to our models of behavior (a point that we elaborate on later). Second, viewing behavioral development through the lens of neuroscience may shed new light on the mechanism(s) that underlie behavior and behavioral development, thereby moving us beyond the level of description to the level of process. Third, when we insert the molecular biology of brain development into the equation, a more synthetic view of the child becomes possible—genes, brain, and behavior. This broader view permits us to move beyond simplistic notions of gene-environment interactions and instead talk about the ways that specific experiences influence specific neural circuits, which influence the expression of particular genes, which influence how the brain functions and how the child behaves.

Chapter 1

Brain Development and Neural Plasticity

A Précis to Brain Development

Before discussing the details of neural development, it is important to understand that brain development, at the species level, has been shaped over many thousands of generations by selective pressures that drive evolution. According to Knudsen (2003a), this portion of biological inheritance is responsible for nearly all of the genetic influences that shape the development and function of the nervous system, the majority of which have proven to be adaptive for the success of any given species. These influences determine both the properties of individual neurons and the patterns of neural connections. As a result, these selective pressures delimit an individual’s cognitive, emotional, sensory, and motor capabilities.

There is, however, a small portion of biological inheritance that is unique to the individual and results from the novel combination of genes that the child receives from the parents. Because there is no history to this gene pattern, any new phenotype that is produced has never been subjected to the forces of natural selection and is unlikely to confer any selective advantage for that individual. However, this small portion of biological inheritance is particularly important for driving evolutionary change, as novel combinations of genes or mutations that do confer a selective advantage will increase in the gene pool, while those that result in maladaptive phenotypes will die out (Knudsen, personal communication).

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