Neuroscience

The discovery of dopamine in 1957-8 was one of the seminal events in the development of modern neuroscience, and has been extremely important for the development of modern therapies of neurological and psychiatric disorders. Dopamine has a fundamental role in almost all aspects of behavior — from motor control to mood regulation, cognition and addiction and reward — and dopamine research has been unique within the neurosciences in the way it has bridged basic science and clinical practice. Over the decades, research into the role of dopamine in health and disease has been at the forefront of modern neuroscience.

Neuronal responses to identically presented stimuli are extremely variable. This variability has in the past often been regarded as “noise.” At the single neuron level, interspike interval (ISI) histograms constructed during either spontaneous or stimulus-evoked activity reveal a Poisson type distribution. These observations have been taken as evidence that neurons are intrinsically “noisy” in their firing properties. More recent attempts to measure the information content of single neuron spike trains have revealed that a surprising amount of information can be coded in spike trains even in the presence of trial-to-trial variability. Multiple single unit recording experiments have suggested that variability formerly attributed to noise in single cell recordings may instead simply reflect system-wide changes in cellular response properties. These observations raise the possibility that, at least at the level of neuronal coding, the variability seen in single neuron responses may not simply reflect an underlying noisy process. They further raise the very distinct possibility that noise may in fact contain real, meaningful information which is available for the nervous system in information processing. To understand how neurons work in concert to bring about coherent behavior and its breakdown in disease, neuroscientists now routinely record simultaneously from hundreds of different neurons and from different brain areas, and then attempt to evaluate the network activities by computing various interdependence measures including cross correlation, phase synchronization, and spectral coherence. This book examines neuronal variability from theoretical, experimental, and clinical perspectives.

This text is the second edition of this book. It expands the widely acclaimed 1981 book, filling more gaps between EEG and the physical sciences. EEG opens a “window on the mind” by finding new connections between psychology and physiology. Topics include synaptic sources, electrode placement, choice of reference, volume conduction, power and coherence, projection of scalp potentials to dura surface, dynamic signatures of conscious experience, and neural networks immersed in global fields of synaptic action.

The book links the analysis of the brain mechanisms of emotion and motivation to the wider context of what emotions are, what their functions are, how emotions evolved, and the larger issue of why emotional and motivational feelings and consciousness might arise in a system organized like the brain. The topics in motivation covered are hunger, thirst, sexual behaviour, brain-stimulation reward, and addiction. The book proposes a theory of what emotions are, and an evolutionary, Darwinian, theory of the adaptive value of emotion, and then describes the brain mechanisms of emotion. The book examines how cognitive states can influence emotions, and in turn, how emotions can influence cognitive states. The book also examines emotion and decision-making, with links to the burgeoning field of neuroeconomics. The book describes the brain mechanisms that underlie both emotion and motivation in a scientific form that can be used by both students and scientists in the fields of neuroscience, psychology, cognitive neuroscience, biology, physiology, psychiatry, and medicine.

Epilepsy is one of the most common disorders of the brain, and these patients often suffer from memory problems. There are a number of reasons for this: seizures can directly affect the brain in ways that disturb memory; epilepsy often results from trouble in brain regions closely linked to memory; the treatment of epilepsy can affect memory; epilepsy can cause psychological problems, like depression, which interfere with memory. This book reviews all aspects of the relationship between this common and potentially serious neurological disorder and memory, one of the core functions of the human mind. The chapters review the history of the subject; the clinical features of memory disorder in epilepsy; neuropsychological, neuroradiological, neuropathological, and electrophysiological findings; the roles of anticonvulsant side effects and psychiatric disorder; and the scope for memory support and rehabilitation. The study of patients with epilepsy has revealed much about the workings of memory, yet there has been no recent review of this field of research. This book aims to this gap.

This book provides a comprehensive, easy-to-read survey of excitatory amino acids and synaptic transmission. It begins with descriptions of the structure, function, and pharmacology of both the ionotropic and the metabotropic glutamate receptors and the glutamate transporters. Subsequent chapters deal with molecular aspects of the regulation of glutamatergic transmission, including receptor trafficking, the role of glutamate transport, the unique molecular architecture of the synapses (post-synaptic density), and the signal transduction pathways mediated by glutamate. Also unique to the book is a chapter on synaptic plasticity that covers long-term potentiation and long-term depression in relationship to synaptic function. It is striking that glutamate is implicated in most of the major neurological diseases, such as stroke, Alzheimer's disease, and schizophrenia.

This book studies the organization of the white matter pathways of the brain. The book analyzes and synthesizes the corticocortical and corticosubcortical connections of the major areas of the cerebral cortex in the rhesus monkey. The result is a detailed understanding of the constituents of the cerebral white matter and the organization of the fiber tracts. The findings from the thirty-six cases studied are presented on a single template brain, facilitating comparison of the locations of the different fiber pathways. The summary diagrams provide a comprehensive atlas of the cerebral white matter. The text is enriched by close attention to functional aspects of anatomical observations. The clinical relevance of the pathways is addressed throughout the text and a chapter is devoted to human white matter diseases. The introductory account gives a detailed historical background. Translations of seminal original observations by early investigators are presented, and when these are considered in the light of the authors' new observations, many longstanding conflicts and debates are resolved.

A well-known example of filling-in involves the blind spot, a region in the back of the eye that is devoid of photoreceptors. The term blind spot is somewhat of a misnomer, because the corresponding region of visual space is not simply perceived as dark, as one would expect. Instead, it is “filled-in” with the same color and texture as the surrounding background. This phenomenon is often considered as little more than a curiosity. However, this book argues that completion mechanisms similar to those that fill in the blind spot are pervasive and necessary for normal perception. The book reviews evidence suggesting a link between particular neural processes and the perception of filling-in. It then introduces the idea that these processes can instigate various types of long-term neural plasticity, which may underlie recovery and rehabilitation after peripheral injury, as well as other types of skill learning. The connection between completion phenomena and long-term plasticity is explored not only in the visual system, but also in the auditory, somatosensory, and motor systems.

This book describes current information about the three areas mentioned in the title: neuronal migration and development, degenerative brain diseases, and neural plasticity and regeneration. The chapters in the first section of the book examine the cellular and molecular mechanisms by which neurons are generated from the ventricular zone in the forebrain and migrate to their destinations in the cerebral cortex. This description of cortical development also includes discussions of the Cajal-Retzius cell. Another chapter provides insight about the development of another forebrain region, the hypothalamus. The remaining chapters of the first section examine the clinical relevance of brain development in certain disease states in humans. The second section begins with details about the dopaminergic neurons in the substantia niger and their loss in Parkinson's disease. Two subsequent chapters describe changes in brain aging, including changes in the numbers of myelinated axons. Other chapters in this section describe important cellular and molecular changes found in Alzheimer's disease and human epilepsy. The last section begins with a chapter on how the brain's own stem cells provide newly generated neurons to the hippocampal dentate gyrus and how these neurons become integrated into neural circuitry. Then two chapters examine some of the neuroplastic changes that take place in motor and sensory cortices of awake behaving primates. The concluding two chapters address the issue of regeneration in the injured spinal cord and the factors that may contribute to its success.

This book provides an introduction to functional magnetic resonance imaging (fMRI), the scanning technique that allows the mapping of active processes within the brain. There are six sections to the book, with chapters from an international team. Part I provides a broad overview of the field and sets the context. Part II describes the physiological and physical background to fMRI, including coverage of the hardware required and pulse-sequence selection. Practical issues involving experimental design of the paradigms, psycho-physical stimulus delivery, and subject response are covered in Part III, followed by a comprehensive treatment of data analysis in Part IV. Part V deals with practical applications of the technique in the field of neuroscience and in clinical practice. The final section describes how fMRI can be integrated with other neuro-electromagnetic functional mapping techniques.