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Nerve Membranes: A Study of the Biological and Chemical Aspects of Neuron–Glia Relationships presents the various aspects of neuronal and glial structure and function. This book provides an interdisciplinary approach to the analysis of neuron–glia relationships and of membranes in the nervous system. Comprised of seven chapters, this book begins with an overview of the function of the biological membranes to improve, retard, and regulate the rate of cellular reactions. This text then determines the differences in the organization of the cells in the nervous system in the vertebrates and the invertebrates. Other chapters examine the role of certain intermolecular forces and of water in the organization of lipid–protein and lipid–lipid associations. This book reviews as well the theories of biological membrane structure and considers how these contribute towards understanding the methods by which membranes perform their role. This book is a valuable resource for neuroscientists, neurochemists, and researchers.
An overview of recent experimental and theoretical developments in the field of the physics of membranes, including new insights from the past decade. The author uses classical thermal physics and physical chemistry to explain our current understanding of the membrane. He looks at domain and 'raft' formation, and discusses it in the context of thermal fluctuations that express themselves in heat capacity and elastic constants. Further topics are lipid-protein interactions, protein binding, and the effect of sterols and anesthetics. Many seemingly unrelated properties of membranes are shown to be intimately intertwined, leading for instance to a coupling between membrane state, domain formation and vesicular shape. This also applies to non-equilibrium phenomena like the propagation of density pulses during nerve activity. Also included is a discussion of the application of computer simulations on membranes. For both students and researchers of biophysics, biochemistry, physical chemistry, and soft matter physics.
CELL TYPES IN THE THALAMUS AND CORTEX -- INTRINSIC MEMBRANE PROPERTIES -- SYNAPTIC PROPERTIES -- GLUTAMATERGIC DRIVERS AND MODULATORS -- FIRST AND HIGHER ORDER THALAMIC RELAYS -- THALAMIC CIRCUITRY -- BRIEF OVERVIEW OF CORTICAL ORGANIZATION -- CLASSIFICATION OF THALAMOCORTICAL AND CORTICOTHALAMIC MOTIFS -- SPIKE TIMING AND THALAMOCORTICAL INTERACTIONS -- PARALLEL PROCESSING OF SENSORY SIGNALS TO CORTEX -- THALAMOCORTICAL SUBSTRATES OF ATTENTION -- CORTICOTHALAMIC CIRCUITS LINKING SENSATION AND ACTION.
Membrane Physiology (Second Edition) is a soft-cover book containing portions of Physiology of Membrane Disorders (Second Edition). The parent volume contains six major sections. This text encompasses the first three sections: The Nature of Biological Membranes, Methods for Studying Membranes, and General Problems in Membrane Biology. We hope that this smaller volume will be helpful to individuals interested in general physiology and the methods for studying general physiology. THOMAS E. ANDREOLI JOSEPH F. HOFFMAN DARRELL D. FANESTIL STANLEY G. SCHULTZ vii Preface to the Second Edition The second edition of Physiology of Membrane Disorders represents an extensive revision and a considerable expansion of the first edition. Yet the purpose of the second edition is identical to that of its predecessor, namely, to provide a rational analysis of membrane transport processes in individual membranes, cells, tissues, and organs, which in tum serves as a frame of reference for rationalizing disorders in which derangements of membrane transport processes playa cardinal role in the clinical expression of disease. As in the first edition, this book is divided into a number of individual, but closely related, sections. Part V represents a new section where the problem of transport across epithelia is treated in some detail. Finally, Part VI, which analyzes clinical derangements, has been enlarged appreciably.
One of the most active and productive areas of biological science in the past decade has been the study of the biochemical and biophysical prop erties of cell membranes. There is little doubt that membranes are essen tial components of all cellular systems and that each type of membrane manifests specific and characteristic cellular functions. In the nervous system, important events such as neurotransmission, receptor binding, ion transport, axonal transport, and cell uptake are all known to take place within the neural cell membrane. Phospholipids, one of the major components of membranes, not only provide the membrane with its structural integrity and physical proper ties, but also play an important role in regulating membrane function. Attention has recently been focused on the asymmetric localization of these molecules, the identification of discrete metabolic pools of phospholipids within the membrane matrix, and their involvement in sig nal transmission. Although synaptic membranes generally lack an active mechanism for the de novo biosynthesis of phospholipids, a number of enzymic routes are present for their interconversions and for facilitating metabolic turnover. Metabolites generated during the interconversion reactions may also exert a great influence in modulating membrane func tions. The phosphogylcerides of neural membranes are especially enriched in polyunsaturated fatty acids. However, only very small amounts of these fatty acids are present in the free form, and they are maintained in dynamic equilibrium with the membrane phospholipids.
Covers all aspects of epilepsy, from basic mechanisms to diagnosis and management, as well as legal and social considerations.
This solid introduction uses the principles of physics and the tools of mathematics to approach fundamental questions of neuroscience.
In this, the post-genomic age, our knowledge of biological systems continues to expand and progress. As the research becomes more focused, so too does the data. Genomic research progresses to proteomics and brings us to a deeper understanding of the behavior and function of protein clusters. And now proteomics gives way to neuroproteomics as we beg