After providing basic background on transplantation, brain structure, and development, the book discusses Parkinson's disease, the use of transplants to influence localized brain functions, circuit reconstruction, and genetic engineering and other future technologies.
we might seek alternative sources of donor tissues. Genetic en- neering, expansion of precursor cells, generation of immortalized cell lines, and transplantation between species are all under active investigation. Although significant difficulties remain for each of these alternatives, the problems appear soluble and relevant knowledge is expanding rapidly. As we enter the twenty-first century, the place of neural tra- plantation in experimental neuroscience is continuing to evolve. Rather than being a topic in its own right, neural transplantation increasingly serves as just another technique in the researcher's armory--alongside lesions, pharmaceuticals, gene transfer, and a variety of other techniques--for the experimental manipulation of brain structure and function. This is particularly true for studies of degeneration, plasticity, regeneration, and recovery of function in the nervous system, topics of increasing importance as experimental neurobiology is required to serve the higher needs of neurological and mental health in aging societies. Within this evolving context, Neural Transplantation Methods seeks to serve a particular need: to provide experimental neu- scientists with a source book of information to enable them to select and adapt transplantation techniques to their own expe- mental programs. All authors have been asked to address prac- cal issues, to enable the reader to assess what is available, what are the alternatives, what are the practical issues to be resolved in applying a particular protocol and getting it to work reliably in their unique experimental context.
The United States military is arguably the most intensely technological, complex enterprise in existence. When compared to the gross domestic products of other countries, the Department of Defense (DoD) budget ranks above all but about 20 nations. If viewed as a company, it would be the largest globally with the most employees. Major investments in weapons systems using advanced technologies provide an advantage over competing systems. Each weapon, platform, vehicle, and person in an operating force is a node in one or more advanced networks that provide the ability to rapidly form a coherent force from a large number of broadly distributed elements. DoD's ability to create and operate forces of this nature demands a competent understanding by its workforce of the composition, acquisition, and employment of its technology-enabled forces. Review of Specialized Degree-Granting Graduate Programs of the Department of Defense in STEM and Management focuses on the graduate science, technology, engineering, mathematics and management (STEM+M) education issues of the Air Force, Navy, and Marines. This report assesses the cost, benefits, and organizational placement of DoD institutions that grant degrees in STEM+M and evaluates alternative ways - for example, civilian institutions and distance learning - to ensure adequate numbers and high-quality education outcomes for DoD personnel."--Publisher's description.
This book begins with a synopsis of experimental work underlying degeneration and recovery in the nervous system, which is then discussed in the context of strategies to repair the central nervous system (CNS) and peripheral nervous system (PNS). The major part of the book is given over to the approach involving the use of transplanted tissues to replace and restore disrupted neural networks. This experimental work has formed the basis for the emerging clinical trials employing neural grafts for diseases such as Parkinson's and Huntington's, which are discussed in detail. The book then goes on to discuss newer cellular strategies involving the manipulation of neural cells both in culture and genetically, an approach that may ultimately be employed in the clinical situation. Neural Repair, Transplantation and Rehabilitation is unique in bridging the gap from experimental studies to clinical trials, whilst also providing the non-specialist with a background in rehabilitation strategies as well as basic neuroscience. It is recommended for all those involved in the management of patients with degenerative and traumatic injuries to the nervous system.
Four years ago the first international symposium dealing with neural transplan tation was organized as a satellite conference to the annual meeting of the Society for Neuroscience in Los Angeles, California. The expanded proceed ings of that symposium were published by Springer-Verlag in 1983 in a volume entitled Neural Tissue Transplantation Research. We were sufficiently pleased with the results of that effort to organize a second satellite international sympo sium on Neural Transplantation and Regeneration in conjunction with the 13th Annual Meeting of the Society for Neuroscience in Boston in the fall of 1983. Paralleling the growing body of research dealing with various aspects of neural transplantation, the scope of this second symposium was broadened to include not only transplantation but also regeneration. Additionally, topics of clinical interest were addressed as well as issues of basic research. The promise apparent in that first conference is still seen in the second as more and more investigators apply their talents in an attempt to understand this infant field of research. The present volume represents an expanded version of the material presented at the second symposium. We wish to thank all of the contributors to the conference and to this volume for their insight and their assistance.
erebellar ataxia is a failure in muscular coordination that re C sults from a slow, progressive deterioration of neurons in the cerebellum. An estimated 150,000 people are affected by the he reditary ataxias and related disorders in the United States. At present, there is no known cure. In an experimental treatment aimed at reconstructing the damaged pathway through exog enous neuronal supplementation, genetically ataxic mice have been used for intracerebral grafting of genetically healthy cerebellar neuroblasts, and evidence has been obtained for graft-induced en hancement of behavioral responses after bilateral cerebellar grafts. Such results are encouraging and underscore the potential of the neural grafting technique in restoring cerebellar function. How ever, many of the pathological and biochemical mechanisms in the interaction between grafted tissue and the host brain need to be further elucidated in extensive experimental studies, and great cau tion must be used in contemplating the theoretical feasibility of a possible application in humans.
The field of neural transplantation is at a crucial stage, with important clinical trials on transplantation in patients with Parkinson's disease nearing completion and novel, alternative approaches to fetal transplantation being developed. This timely book brings together leading neuroscientists, clinicians, and cell and developmental biologists to discuss the use of neural transplants in neurodegenerative disorders, such as Parkinson's disease, Huntington's chorea, amyotrophic lateral sclerosis, multiple sclerosis and spinal cord injury. There is also extensive coverage of the potential alternatives to freshly derived fetal tissue as the source of transplants, for example xenografts, encapsulated cells and immortalized stem cells. With authoritative contributions and lively discussion sections, this book presents much new and exciting work in this field and identifies promising new research directions.
Functional Neural Transplantation IV: Translation to Clinical Application, Volume 230 provides the current status of cell transplantation in the nervous system, with a focus on the conditions for achieving structural repair and functional recovery after brain damage or in neurodegenerative disease. New to this release are chapters that delve into the Mechanisms and Use of Neural Transplants for Brain Repair, Reprogramming of Somatic Cells: iPS and iN Cells, Brain Repair from Intrinsic Cell Sources: Turning Reactive Glia into Neurons, and Ex Vivo Gene Therapy for the Treatment of Neurological Disorders, Preparation, Characterization and Banking of Clinical-grade Cells for Neural Transplantation. As the fourth in a periodic series of updates at 5-7 year intervals, this volume highlights recent developments related to the application of advances in cellular and molecular science, providing an understanding of the fundamental principles of neuroplasticity and regeneration in the brain and spinal cord, and also addressing the topic of the power of pluripotent stem cells to generate new sources of precisely specified neurons for utilization in brain repair. - Comprehensive set of critical reviews covering the field - Presents state-of-the-art topics in science and translational medicine - Written by international leaders in the field of neural transplantation
This issue of Progress in Brain Research is split over 2 volumes, bringing together cutting-edge research on Functional Neural Transplantation. The 2 volumes review current knowledge and understanding, provide a starting point for researchers and practitioners entering the field, and build a platform for further research and discovery. - Leading authors review the state-of-the-art in their field of investigation, and provide their views and perspectives for future research - Chapters are extensively referenced to provide readers with a comprehensive list of resources on the topics covered - All chapters include comprehensive background information and are written in a clear form that is also accessible to the non-specialist
This unique reference presents studies from leading laboratories that are studying the effects of CNS transplants on neuronal plasticity and recovery of function after CNS injury. Topics covered include tropic influences, reinnervation patterns, and prevention of cell death that range from pre-clinical models of Parkinson's disease in primates to studies of restoration of circadian rhythms in rats. Techniques of neurotransplantation are presented, including current limitations and future projections of advancement.