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Distinguished researchers review the latest scientific understanding of spinal cord injury (SCI), focusing on the mechanisms causing paralysis after spinal cord trauma, the molecular determinants of neural regeneration, and methods for improving damaged function. The authors examine the role of intracellular Ca2+ in neuronal death, the possibility of spinal learning, growth-promoting molecules for regenerating neurons, and the biochemistry and cell biology of microtubules. Among the treatment possibilities discussed are cell transplantation strategies beyond the use of fetal spinal cord tissue, remyelination in spinal cord demyelination models, high steroid therapy immediately after SCI, and the mixed use of anti- and proinflammatories. Comprehensive and highly promising, Neurobiology of Spinal Cord Injury summarizes and integrates the great progress that has been made in understanding and combating the paralysis that follows spinal cord injury.
This volume is the most recent installment of the Progress in Motor Control series. It contains contributions based on presentations by invited speakers at the Progress in Motor Control VIII meeting held in Cincinnati, OH, USA in July, 2011. Progress in Motor Control is the official scientific meeting of the International Society of Motor Control (ISMC). The Progress in Motor Control VIII meeting, and consequently this volume, provide a broad perspective on the latest research on motor control in humans and other species.
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...
Leading neuroscience researchers offer a fresh perspective on neuronal function by examining all its many components-including their pertubation during major disease states-and relate each element to neuronal demands. Topics range from the dependency of neurons on metabolic supply, as well as on both ion and transmitter homeostasis, to their close interaction with the myelin sheath. Also addressed are the astrocytic signaling system that controls synaptic transmission, the extracellular matrix and space as communication systems, the role of blood flow regulation in neuronal demand and in blood-brain barrier function, and inflammation and the neuroimmune system. Insightful and integrative, The Neuronal Environment: Brain Homeostasis in Health and Disease demonstrates a clear new understanding that neurons do not work in isolation, that they need constant interactions with other brain components to process information, and that they are not the only information processing system in the brain.
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...
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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.
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