Neural Stem cells – New perspectives Posted by R Santhosh Kalash on 10/20/2013 12:15:00 pm No comments

During the last two decades stem cell biology has changed the field of basic research in life science as well as our perspective of its possible outcomes in medicine. At the beginning of the nineties, the discovery of neural stem cells in the mammalian central nervous system (CNS) made the generation of new neurons a real biological process occurring in the adult brain. Since then, a vast community of neuroscientists started to think in terms of regenerative medicine as a possible solution for incurable CNS diseases, such as traumatic injuries, stroke and neurodegenerative disorders. Nevertheless, in spite of the remarkable expansion of the field, the development of techniques to image neurogenesis in vivo, sophisticated in vitro stem cell cultures, and experimental transplantation techniques, no efficacious therapies capable of restoring CNS structure and functions through cell replacement have been convincingly developed so far. Deep anatomical, developmental, molecular and functional investigations have shown that new neurons can be generated only within restricted brain regions under the control of specific environmental signals. In the rest of the CNS, many problems arise when stem cells encounter the mature parenchyma, which still behaves as 'dogmatically' static tissue. More recent studies have added an additional level of complexity, specifically in the context of CNS structural plasticity, where stem cells lie within germinal layer-derived neurogenic sites whereas progenitor cells are widespread through the CNS.

Hence, two decades after the seminal discovery of neural stem cells, the real astonishing fact is the occurrence of such cells in a largely nonrenewable tissue. Still, the most intriguing question is which possible functional or evolutionary reasons might justify such oddity. In other self-renewing tissues, such as skin, cornea, and blood, the role of stem cells in the tissue homeostasis is largely known and efficacious stem cell therapies are already available. The most urgent question is whether and how the potential of neural stem cells could be exploited within the harsh territory of the mammalian CNS. In this case, unlike other tissues, more intense and time-consuming basic research is required before achieving a regenerative outcome. The road of such research should travel through a better knowledge of several aspects which are still poorly understood, including the developmental programs leading to postnatal brain maturation, the heterogeneity of progenitor cells involved, the bystander effect that stem cell grafts exert even in the absence of cell replacement, and the cohort of stem cell-to-tissue interactions occurring both in homeostatic and pathological conditions.

In this book, the experience and expertise of many leaders in neural stem cell research are gathered with the aim of making the point on a number of extremely promising, yet unresolved, issues.

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Divided Brains: The Biology and Behaviour of Brain Asymmetries Posted by R Santhosh Kalash on 10/20/2013 10:01:00 am No comments

Asymmetry of the brain and behavior (lateralization) has traditionally been considered unique to humans. However, research has shown that this phenomenon is widespread throughout the vertebrate kingdom and found even in some invertebrate species. A similar basic plan of organization exists across vertebrates. Summarizing the evidence and highlighting research from the last twenty years, the authors discuss lateralization from four perspectives – function, evolution, development and causation – covering a wide range of animals, including humans. The evolution of lateralization is traced from our earliest ancestors, through fish and reptiles to birds and mammals. The benefits of having a divided brain are discussed, as well as the influence of experience on its development. A final chapter discusses outstanding problems and areas for further investigation. Experts in this field, the authors present the latest scientific knowledge clearly and engagingly, making this a valuable tool for anyone interested in the biology and behavior of brain asymmetries. Draws on neuroscience, behaviour, psychology and evolution to examine the important and diverse properties of lateralization Integrates the latest research on both non-human and human animals, providing a complete perspective on the subject Authored by three leaders in the field, who highlight the past twenty years of research. 

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Encyclopedia of Neuroscience Posted by R Santhosh Kalash on 9/12/2013 01:09:00 pm No comments

Neuroscience is a rapidly expanding endeavor devoted to unraveling the structure and function of the nervous system. It relies on, and keeps close relations to, a number of other disciplines, such as mathematics, physics, chemistry, engineering, computer science, genetics, molecular biology, biochemistry, medicine and philosophy. Indeed, many of its recent successes result from the application of ideas, concepts and methods borrowed from these fields. Thus, neuroscience has become the archetype for interdisciplinary undertakings. This convergence of influences accounts for part of its enormous attractiveness and fascination to students, researchers and lay persons from various walks of life or science. Many of neuroscience’s most creative and productive investigators have been lured into the field not only by the excitement inherent in the possibility of uncovering the secrets of the human mind, but by the appeal of venturing into a vast unknown land, requiring the development of new tools for its effective cultivation. Far from simply satisfying our intellectual curiosity, however, neuroscience has become ever more important as a theoretical ground for practical applications in medicine, in particular neurology, and other disciplines.

The explosion of neuroscience has made it virtually impossible for individuals to follow all the ramifications and fast developments in the many corners and branches of this science. This Encyclopedia has therefore been designed for a wide variety of readers, from members of the lay public to students, practitioners and researchers in biology, medicine, psychology, sociology, philosophy and their associated auxiliary fields. Moreover, it should also prove useful to advanced researchers of biology and neuroscience who wish to stay abreast of current developments outside their immediate areas of expertise.

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The Senses: A Comprehensive reference Posted by R Santhosh Kalash on 9/12/2013 01:07:00 pm No comments

This major new publication stands as the first up-to-date, cutting-edge, comprehensive reference work combining volumes on all major sensory modalities in one set. Under the guidance of a distinguished team of international experts, these 6 volumes contain 234 articles from renowned scientists laying out our current knowledge on the anatomy, physiology, and molecular biology of sensory organs. Topics covered include the perception, psychophysics, and higher order processing of sensory information, as well as disorders and new diagnostic and treatment methods. Written for a wide audience, this reference work provides students, scholars, medical doctors, and anyone interested in neuroscience a comprehensive overview of the knowledge accumulated on the function of sense organs, sensory systems, and how the brain processes sensory input. Leading scholars from around the world contributed articles, making The Senses a truly international portrait of sensory physiology.

The set is the definitive reference on sensory neuroscience on the market, and will provide the ultimate entry point into the review and original literature in Sensory Neuroscience, and be a natural place for interested students and scientists to deepen their knowledge.

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The Synaptic organization of the brain; Fifth Edition Posted by R Santhosh Kalash on 9/12/2013 01:05:00 pm No comments

The most significant event since the publication of the previous edition has been the sequencing of the mouse and human genomes, opening up new horizons for all of biology. For the brain, interpreting the functions of the genes depends on understanding how the proteins they produce function at different sites within a nerve cell, and how each nerve cell contributes to the circuits that carry out the fundamental operations of processing information in each brain region. This is the subject matter of synaptic organization.

Taking advantage of the genomic and proteomic data are new methods, including new applications of patch clamp recordings, powerful new microscopic methods based on two-photon laser confocal microscopy, gene-targeting to enable specific genes and proteins to be labeled, knocked-in or knocked-out, and fluorescent methods that provide dramatic images of cells as they interact synaptically with their neighbors under a variety of different functional states. Previously remote problems, such as the functions of dendrites and dendritic spines, are being attacked directly with the new methods.

In parallel with the experimental advances have come ever more powerful computational models that are building a deeper theoretical basis for brain function. Just as more powerful accelerators give physicists the ability to probe more deeply into the atom and the fundamental forces that determine the nature of matter and energy, so the new methods are giving neuroscientists the ability to probe more deeply into the neuron and its synaptic circuits and the fundamental properties that determine how information is processed in the brain. The results continue to constitute a quiet revolution in how we understand the neural basis of behavior, as potentially profound for brain science as the quantum theory has been for physics.

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Protein trafficking in Neurons Posted by R Santhosh Kalash on 9/12/2013 01:03:00 pm No comments

The efficient delivery of cellular constituents to their proper location is of fundamental importance for all cells and is of particular interest to neuroscientists, because of the unique functions and complex architecture of neurons. Protein Trafficking in Neurons examines mechanisms of protein trafficking and the role of trafficking in neuronal functioning from development to plasticity to disease. The book is divided into seven sections that review mechanisms of protein transport, the role of protein trafficking in synapse formation, exo- and endocytosis, transport of receptors, trafficking of ion channels and transporters, comparison of trafficking mechanisms in neuronal vs. non-neuronal cell types, and the relationship between trafficking and neuronal diseases such as Alzheimer's, Huntington's and Prion Diseases.

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Neuroscience at a glance Posted by R Santhosh Kalash on 9/12/2013 01:01:00 pm No comments

It is designed primarily for undergraduate medical students as a revision text or review of basic neuroscience mechanisms, rather than a comprehensive account of the field of medical neuroscience. The book does not attempt to provide a systematic review of clinical neurology. However, it should also be of use for those in clinical training and practice wanting a review and synopsis of the science behind the clinical practice.

This book summaries the rapidly expanding field of neuroscience with reference to clinical disorders, such that the material is set in a clinical context. In general, the later chapters contain more clinical material whilst the earlier ones contain a section towards the end outlining applied neuroscience. However, learning about the organisation of the nervous system purely from clinical disorders is short sighted as the changing nature of medical neuroscience means that areas with little clinical relevance today may become more of an issue in the future. An example of this is ion channels and the recent burgeoning of a host of char. Nelopathies. For this reason some chapters focus more on scientific mechanisms with less clinical emphasis.

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Ions in the Brain: Normal Function, Seizures, and Stroke Posted by R Santhosh Kalash on 9/12/2013 12:57:00 pm No comments

Neuroscience research has come to a paradoxical stage. During the past century and a half, we have learned a great deal about the elementary processes that govern the functioning of individual neurons and glial cells and of the junctions that connect them. Yet, we must admit that we have no solid theory, not even a conceptual framework, of the workings of the system as a whole. The paradox lies in the fact that, in spite of our bafflement and frustrating inability to understand its normal operation, we have gained considerable insight into the ways in which cerebral function can go wrong. This, the mechanisms of some of the most severe afflictions that can befall the brain, is a main topic of this volume. In this matter, the pathophysiology of the brain, we might say that a major chapter has just been completed, at least in outline, while the next one is just beginning to be written. We have a good understanding of the way in which cells and groups of cells behave when seized by epileptic fits and of what happens, on a  microscopic scale, when brain cells are deprived of oxygen. We have been able to observe the tides of ions flowing into and out of cells, and we have learned how ion fluxes feed back on the ion channels through which they pass. This is the part that is more or less complete, save some missing details, and it is the main topic of this book. The next chapter, dealing with molecular and submolecular processes, which is still in an incipient stage, is touched on but not reviewed in detail.

The emphasis in the book is on advances made in the past few decades, without neglecting the road by which we have arrived at the present stage of knowledge. A true historical survey cannot be accommodated in this small volume, but each major topic is introduced by highlighting the historical background, casting a backward glance at the origins and the evolution of current ideas. Each chapter concludes with a selection of the major theses developed on the preceding pages. As the reference section attests, the literature is enormous.

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Theoretical neuroscience: Computational and Mathematical Modeling of Neural Systems Posted by R Santhosh Kalash on 9/12/2013 12:25:00 pm No comments

Theoretical analysis and computational modeling are important tools for characterizing what nervous systems do, determining how they function, and understanding why they operate in particular ways. Neuroscience encompasses approaches ranging from molecular and cellular studies to human psychophysics and psychology. Theoretical neuroscience encourages cross-talk among these sub-disciplines by constructing compact representations of what has been learned, building bridges between different levels of description, and identifying unifying concepts and principles. In this book, we present the basic methods used for these purposes and discuss examples in which theoretical approaches have yielded insight into nervous system function.

The questions what, how, and why are addressed by descriptive, mechanistic, and interpretive models, each of which we discuss in the following chapters. Descriptive models summarize large amounts of experimental data compactly yet accurately, thereby characterizing what neurons and neural circuits do. These models may be based loosely on biophysical, anatomical, and physiological findings, but their primary purpose is to describe phenomena not to explain them. Mechanistic models, on the other hand, address the question of how nervous systems operate on the basis of known anatomy, physiology, and circuitry. Such models often form a bridge between descriptive models couched at different levels. Interpretive models use computational and information theoretic principles to explore the behavioral and cognitive significance of various aspects of nervous system function, addressing the question of why nervous system operates as they do.

It is often difficult to identify the appropriate level of modeling for a particular problem. A frequent mistake is to assume that a more detailed model is necessarily superior. Because models act as bridges between levels of understanding, they must be detailed enough to make contact with the lower level yet simple enough to yield clear results at the higher level.

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Neuroscience: Third Edition Posted by R Santhosh Kalash on 9/11/2013 10:16:00 am No comments

Whether judged in molecular, cellular, systemic, behavioral, or cognitive terms, the human nervous system is a stupendous piece of biological machinery. Given its accomplishments—all the artifacts of human culture, for instance—there is good reason for wanting to understand how the brain and the rest of the nervous system works. The debilitating and costly effects of neurological and psychiatric disease add a further sense of urgency to this quest. The aim of this book is to highlight the intellectual challenges and excitement—as well as the uncertainties—of what many see as the last great frontier of biological science. The information presented should serve as a starting point for undergraduates, medical students, graduate students in the neurosciences, and others who want to understand how the human nervous system operates. Like any other great challenge, neuroscience should be, and is, full of debate, dissension, and considerable fun. All these ingredients have gone into the construction of the third edition of this book; we hope they will be conveyed in equal measure to readers at all levels.

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Neurological Foundations of Cognitive Neuroscience Posted by R Santhosh Kalash on 9/10/2013 05:04:00 pm No comments

It is an exciting time for the discipline of cognitive neuroscience. In the past 10 years we have

witnessed an explosion in the development and advancement of methods that allow us to precisely examine the neural mechanisms underlying cognitive processes. Functional magnetic resonance imaging, for example, has provided markedly improved spatial and temporal resolution of brain structure and function, which has led to answers to new questions, and the reexamination of old questions. However, in my opinion, the explosive impact that functional neuroimaging has had on cognitive neuroscience may in some ways be responsible for moving us away from our roots—the study of patients with brain damage as a window into the functioning of the normal brain. Thus, my motivation for creating this book was to provide a collection of chapters that would highlight the interface between the study of patients with cognitive deficits and the study of cognition in normal individuals.

Each chapter in this book was written by a neurologist who also practices cognitive neuroscience. Each chapter begins with a description of a case report, often a patient seen by the author, and describes the symptoms seen in this patient, laying the foundation for the cognitive processes to be explored. After the clinical description, the authors have provided a historical background about what we have learned about these particular neurobehavioral syndromes through clinical observation and neuropsychological investigation. Each chapter then explores investigations using a variety of methods—single-unit electrophysiological recording in awake-behaving monkeys, behavioral studies of normal healthy subjects, event-related potential and functional neuroimaging studies of both normal individuals and neurological patients—aimed at understanding the neural mechanisms underlying the cognitive functions affected in each particular clinical syndrome.

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Molecular Neuroscience Posted by R Santhosh Kalash on 9/10/2013 03:42:00 pm No comments

This text is designed to give the reader some insight into how neuroscience has been revolutionized at the molecular level in the past decade or so. We hope it will serve as a broad introduction to many of the ingenious approaches molecular biologists have used to fathom neural function and some of the key findings in relation to aspects of neuroscience currently at the cutting edge and important which look like remaining high profile for a little while to come. As such, we trust that this book will provide sufficient familiarity with molecular biology techniques applied to neuroscience discovery that the exciting literature in this area becomes accessible.

The book introduces new methodologies in boxes so as not to disrupt the main text and finally included a glossary of all words which appear in the text in bold as aid and number of appendices providing information which the reader might want to have to hand when trying to unravel a research paper in molecular neuroscience.

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Molecular and Cellular Biology of Neuroprotection in the CNS Posted by R Santhosh Kalash on 9/10/2013 03:39:00 pm No comments

The adult mammalian brain is not well equipped for self-repair. Although neuronal loss reinstalls parts of the molecular machinery that is essential for neuronal development, other factors and processes actively impede regeneration of the damaged brain. Many therapeutic efforts thus aim to promote or inhibit these endogenous pathways. In addition, more radical approaches appear on the horizon, such as replacement of lost neurons with grafted tissue.

Neurorepair, however, is not the topic of this book. Here, we go one step back in the sequence of events that lead eventually to the demise of a neuronal population. This book focuses on the precious period when an initial damaging event evolves into a vast loss of neurons. The time frame might be hours to days in acute brain injury or months to years in chronic neurodegenerative diseases. Given the limited capacity of regeneration, protecting neurons that are on the brink of death is a major challenge for basic and clinical neuroscience, with implications for a broad spectrum of neurological and psychiatric diseases, ranging from stroke and brain trauma to Parkinson´s and Alzheimer´s disease. In recent years, rapid progress has been made in unravelling many of the cellular and molecular players in neuronal death and survival. However, as the field develops into more and more specialized branches, the notion of common pathogenic pathways of neuronal loss might get buried under the wealth of novel data. Thus it seems a timely endeavor to provide an overview on the most exciting recent developments in neuroprotective signaling and experimental neuroprotection.

This book brings together experts from cellular and molecular neurobiology, neurophysiology, neuroanatomy, neuropharmacology, neuroimmunology and neurology. It is my hope that the book serves as a reference text for both basic neuroscientists and clinicians, offering a fresh look at many (certainly not all) of the highly intertwined processes that determine the fate of CNS neurons in the face of acute or chronic insults.

The book is written mostly from the viewpoint of the basic scientist who works at the cellular and molecular level, but who also develops and tests new hypotheses using animal models of acute and chronic brain injury. Although many of the new findings hold promise for therapeutic interventions, their translation into clinically relevant neuroprotective strategies is still in its infancy. If this book helps to bridge this gap, it will certainly be worth the effort.

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Microarrays for the Neurosciences: An Essential Guide Posted by R Santhosh Kalash on 9/10/2013 03:37:00 pm No comments

The effort to sequence the human genome has generated a new discipline, "functional genomics," or the study of the relationship between the genetic code and its biologic potential. Gene expression studies are made possible not only by the decoding of the human genome, but by the development of new technologies. The preeminent technology in this area, DNA microarrays, is helping to revolutionize the field of neuroscience. Rather than looking at one gene at a time, researchers using DNA microarrays can monitor the expression patterns of large numbers of genes simultaneously. Bridging the traditional gap between molecular neurobiology and systems neurobiology, DNA microarray technology has the potential to elevate molecular genetic studies of the nervous system to the system level.

This book provides a comprehensive guide to the use of DNA microarrays in neuroscience and provides approaches that are applicable to other complex biological systems. Human nervous system tissue is remarkably complex. The number of cell types, the architecture, the developmental program, and the importance of environmental factors in development and functioning all pose particular challenges to the researcher using gene expression studies. After an overview of the technology, the book discusses array scanning and image application, statistical methods for array analysis, specific applications of gene expression studies in the central nervous system, the use of postmortem human tissue, and novel methods for using microarray data to develop hypotheses about regulatory networks.

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Handbook of Developmental Cognitive Neuroscience Posted by R Santhosh Kalash on 9/10/2013 02:32:00 pm No comments

Handbook of Developmental Cognitive Neuroscience represents the distillation of the best this new field has to offer; it also reflects a number of strong biases by the editors. One such bias is that the field of developmental cognitive neuroscience must be grounded in basic neurodevelopmental science, particularly developmental neurobiology. To this end, the first part of this volume (Fundamentals of Developmental Neurobiology) is devoted to basic studies and principles of neural development. Here the reader learns about pre- and postnatal neurogenesis, synaptogenesis, and myelination; the effects of sex hormones on brain development; and about development of the hippocampus and prefrontal cortex in particular (given the importance of these regions for cognitive development). A second bias is our emphasis on the importance of methodological advances. Thus, the second part of the volume (Methodological Paradigms) is devoted to describing methods that have proved so important in elucidating brain-behavior relations in the context of cognitive development. These methods include behavioral "marker" tasks, along with event-related potentials (ERPs), functional Magnetic Resonance Imaging (fMRI), and genetic and computational (neural network) modeling. Over the past several years the area of neural plasticity has received tremendous attention by both neuroscientists and behavioral scientists. Indeed, the forces that shape and mold the brain may well represent the "new" developmental psychology, albeit a more mechanistic and reductionistic version than offered by previous generations of developmental psychologists and one that emphasizes development within a lifespan context. That is, the forces that mold the brain's structure and physiology are now recognized to operate well into adulthood (see Tanapat, Hastings, and Gould, chapter 7, this volume). To this end, the third part (Neural Plasticity of Development) is devoted to a discussion of this area, emphasizing both normative and atypical aspects of development.

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Elements of Molecular Neurobiology Posted by R Santhosh Kalash on 9/10/2013 02:30:00 pm No comments

This edition of the popular text incorporates recent advances in neurobiology enabled by modern molecular biology techniques. Understanding how the brain works from a molecular level allows research to better understand behaviours, cognition, and neuropathologies. Since the appearance six years ago of the second edition, much more has been learned about the molecular biology of development and its relations with early evolution. This "evodevo" (as it has come to be known) framework also has a great deal of bearing on our understanding of neuropathologies as dysfunction of early onset genes can cause Neurodegeneration in later life. Advances in our understanding of the genomes and proteomes of a number of organisms also greatly influence our understanding of neurobiology. Well known and widely used as a text throughout the UK, good reviews from students and lecturers. Good complement to Fundamentals of Psychopharmacology by Brian Leonard. This book will be of particular interest to biomedical undergraduates undertaking a neuroscience unit, neuroscience postgraduates, physiologists, pharmacologists. It is also a useful basic reference for university libraries.

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Color Atlas of Neuroscience: Neuroanatomy and Neurophysiology Posted by R Santhosh Kalash on 9/10/2013 02:29:00 pm No comments

Taking a uniquely visual approach to complex subject matter, this pocket Flexibook gives you a full understanding of the basics of neuroscience with 193 exquisite color plates and concise text. Following in the successful tradition of the basic sciences Thieme Flexibooks, this title presents anatomy, physiology, and pharmacology of neuroscience. You will find in-depth coverage of: neuroanatomy, embryology, cellular neuroscience, somatosensory processing, motor control, brain stem and cranial outflow, autonomic nervous system, and much more! The book is designed to supplement larger texts and is ideal as both an introduction to the subject and a complete study guide for exam preparation. It will prove invaluable for all medical and biology students.

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Brain Facts :A Primer on the brain and nervous system Posted by R Santhosh Kalash on 9/10/2013 02:26:00 pm No comments

Neuroscientists have the daunting task of deciphering the mystery of this most complex of all machines: how as many as a trillion nerve cells are produced, grow and organize themselves into effective, functionally active systems that ordinarily remain in working order throughout a person’s lifetime. The motivation of researchers is twofold: to understand human behavior better—from how we learn to why people have trouble getting along together—and to discover ways to prevent or cure many devastating brain disorders.

The more than 1,000 disorders of the brain and nervous system result in more hospitalizations than any other disease group, including heart disease and cancer. Neurological illnesses affect more than 50 million Americans annually at costs exceeding $400 billion. In addition, mental disorders, excluding drug and alcohol problems, strike 44 million adults a year at a cost of some $148 billion. However, during the congressionally designated Decade of the Brain, which ended in 2000, neuroscience made significant discoveries in these areas:

Genetics. Key disease genes were identified that underlie several neurodegenerative disorders—including Alzheimer’s disease, Huntington’s disease, Parkinson’s disease and amyotrophic lateral sclerosis. This has provided new insights into underlying disease mechanisms and is beginning to suggest new treatments. With the mapping of the human genome, neuroscientists will be able to make more rapid progress in identifying genes that either contributes to human neurological disease or that directly cause disease. Mapping animal genomes will aid the search for genes that regulate and control many complex behaviours.

Brain Plasticity. Scientists began to uncover the molecular bases of neural plasticity, revealing how learning and memory occur and how declines might be reversed. It also is leading to new approaches to the treatment of chronic pain.

New Drugs. Researchers gained new insights into the mechanisms of molecular neuropharmacology, which provides a new understanding of the mechanisms of addiction. These advances also have led to new treatments for depression and obsessive compulsive

disorder.

Imaging. Revolutionary imaging techniques, including magnetic resonance imaging and positron emission tomography, now reveal brain systems underlying attention, memory and emotions and indicate dynamic changes that occur in schizophrenia.

Cell Death. The discovery of how and why neurons die, as well as the discovery of stem cells, which divide and form new neurons, has many clinical applications. This has dramatically improved the outlook for reversing the effects of injury both in the brain and spinal cord. The first effective treatments for stroke and spinal cord injury based on these advances have been brought to clinical practice.

Brain Development. New principles and molecules responsible for guiding nervous system development now give scientists a better understanding of certain disorders of childhood. Together with the discovery of stem cells, these advances are pointing to novel strategies for helping the brain or spinal cord regain functions lost to diseases. Federal neuroscience research funding of more than $4 billion annually and private support should vastly expand our knowledge of the brain in the years ahead.

This book only provides a glimpse of what is known about the nervous system, the disorders of the brain and some of the exciting avenues of research that promise new therapies for many neurological diseases.

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