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Cell Therapy, Stem Cells and Brain Repair
As our world continues to evolve, the field of regenerative medicine f- lows suit. Although many modern day therapies focus on synthetic and na- ral medicinal treatments for brain repair, many of these treatments and prescriptions lack adequate results or only have the ability to slow the p- gression of neurological disease or injury. Cell therapy, however, remains the most compelling treatment for neurodegenerative diseases, disorders, and injuries, including Parkinson’s disease, Huntington’s disease, traumatic brain injury, and stroke, which is expanded upon in more detail in Chapter 1 by Snyder and colleagues. Cell therapy is also unique in that it is the only therapeutic strategy tha...
Central Nervous System Diseases
Prominent experimentalists critically review the animal models widely used in developing powerful new therapies for central nervous system diseases. Coverage includes novel uses of animal models of Alzheimer's, Parkinson's, and Huntington's diseases, and studies of aging. Techniques that rely heavily on behavioral analyses, as well as models developed from infusions of neurotoxins and from advances in molecular biology, are thoroughly explicated, as are models developed for more acute neurological conditions, including traumatic brain injury and stroke. Comprehensive and authoritative, Central Nervous System Diseases: Innovative Animal Models from Lab to Clinic offers neuroscientists, pharmacologists, and interested clinicians a unique survey of the most productive animal models of the leading neurological diseases currently employed to develop today's innovative drug therapies.
Neural Stem Cells for Brain and Spinal Cord Repair
Active neuroscientists survey NSCs as potential tools for central nervous system and spinal cord repair by explaining their clinically significant fundamental properties, manipulations, and potential therapeutic paradigms. Their discussion of the fundamental biology of NSCs illustrates the signaling pathways that regulate stem cell division and differentiation, and defines the methods of NSC expansion and propagation, neuromorphogenesis, the factors determining cell fate both in vitro and in situ, and the induction of self-reparative processes within the brain. They also present strategies that may lead to fruitful clinical applications in the near future. These range from the replacement of degenerated, dysfunctional, or maldeveloped cells to the provision of factors that may protect, correct, recruit, promote self-repair, or mediate the connectivity of host cells.
Neural Stem Cells
Over the last decade, neural stem cell research has provided penetrating insights into the plasticity and regenerative potential of the brain. Stem cells have been isolated from embryonic as well as adult central nervous system (CNS). Many non-CNS mammalian tissues also contain stem cells with a more limited repertoire: the replacement of tissue-specific cells throughout the li- time of the organism. Progress has been made in understanding fundamental stem cell properties that depend on the interplay of extrinsic signaling factors with intrinsic genetic programs within critical time frames. With this growing knowledge, scientists have been able to change a neural stem cell’s fate. - der ce...
Mitochondrial Inhibitors and Neurodegenerative Disorders
Mitochondria have long been the Rodney Dangerfield of cellular organelles. Believed to be the remnants of bacterial infection of eukaryotic cells eons ago, the mitochondrion evolved a symbiotic relationship in which it dutifully served as the efficient source of A TP for cell function. The extraordinary dependence of cells on the energy provided by mito chondrial oxidative metabolism of glucose, especially through critical organs such as the heart and brain, is underlined by the fatal consequences of toxins that interfere with the mitochondrial electron transport system. Consistent with their ancestry, the mitochondria have their own DNA that encodes many but not all of their proteins. The m...
Cortico-Subcortical Dynamics in Parkinson’s Disease
The striatum is the principal input structure of the basal ganglia. Numerically, the great majority of neurons in the striatum are spiny projection neurons, which produce the inhibitory output of the striatum to the globus pallidum and substantia nigra. The major glutamatergic afferents to the striatum from the cerebral cortex make monosynaptic contact with spiny projection neurons. The dopaminergic afferents from the substantia nigra also synapse directly on the spiny projection neurons. Thus, the spiny projection neurons play a crucial role in the input–output operations of the striatum by integrating glutamatergic cortical inputs with dopaminergic inputs and producing the output to othe...
Neuroinflammation
In this thoroughly updated and revised edition of his much praised book, Paul L. Wood and a panel of leading researchers capture these new developments in a masterful synthesis of what is known today about the inflammatory mediators and cells involved in neurodegenerative diseases. This second edition contains extensive updates on the mediators produced by microglia and their role in neuroinflammatory-induced neuronal lysis. There is also increased coverage of the animal models used in the study of neuroinflammatory mechanisms, of the new imaging methods that allow the noninvasive evaluation of microglial activation in human neurodegernerative disorders, and of the role of neuroinflammation in amyloid-dependent neuronal lysis.
Neural Development and Stem Cells
Developing the second edition of Neural Development and Stem Cells was neces- tated by the rapid increase in our knowledge of the development of the nervous system. It has become increasingly clear that stem cells are a heterogeneous population that changes extensively during development. Perhaps the most important advance in our understanding of stem cell behavior has been the realization that regionalization of stem cells occurs early in development and this bias toward differentiation in phe- types of neurons or cells characteristic of a particular part of the brain appears to persist even after prolonged culture. We have therefore included additional chapters on olf- tory epithelial stem...
Neurobiology of Aggression
Aggression is a highly conserved behavioral adaptation that evolved to help org- isms compete for limited resources and thereby ensure their survival. However, in modern societies where resources such as food, shelter, etc. are not limiting, aggr- sion has become a major cultural problem worldwide presumably because of its deep seeded roots in the neuronal circuits and neurochemical pathways of the human brain. In Neurobiology of Aggression: Understanding and Preventing Violence, leading experts in the fields of the neurobiology, neurochemistry, genetics, and behavioral and cultural aspects of aggression and violence provide a comprehensive collection of review articles on one of the most im...
The Cell Cycle in the Central Nervous System
Cell Cycle in the Central Nervous System overviews the changes in cell cycle as they relate to prenatal and post natal brain development, progression to neurological disease or tumor formation.Topics covered range from the cell cycle during the prenatal development of the mammalian central nervous system to future directions in postnatal neurogenesis through gene transfer, electrical stimulation, and stem cell introduction. Additional chapters examine the postnatal development of neurons and glia, the regulation of cell cycle in glia, and how that regulation may fail in pretumor conditions or following a nonneoplastic CNS response to injury. Highlights include treatments of the effects of deep brain stimulation on brain development and repair; the connection between the electrophysiological properties of neuroglia, cell cycle, and tumor progression; and the varied immunological responses and their regulation by cell cycle.
