To show the importance of stochastic processes in the change of gene frequencies, the authors discuss topics ranging from molecular evolution to two-locus problems in terms of diffusion models. Throughout their discussion, they come to grips with one of the most challenging problems in population genetics--the ways in which genetic variability is maintained in Mendelian populations. R.A. Fisher, J.B.S. Haldane, and Sewall Wright, in pioneering works, confirmed the usefulness of mathematical theory in population genetics. The synthesis their work achieved is recognized today as mathematical genetics, that branch of genetics whose aim is to investigate the laws governing the genetic structure of natural populations and, consequently, to clarify the mechanisms of evolution. For the benefit of population geneticists without advanced mathematical training, Professors Kimura and Ohta use verbal description rather than mathematical symbolism wherever practicable. A mathematical appendix is included.
To show the importance of stochastic processes in the change of gene frequencies, the authors discuss topics ranging from molecular evolution to two-locus problems in terms of diffusion models. Throughout their discussion, they come to grips with one of the most challenging problems in population genetics--the ways in which genetic variability is maintained in Mendelian populations. R.A. Fisher, J.B.S. Haldane, and Sewall Wright, in pioneering works, confirmed the usefulness of mathematical theory in population genetics. The synthesis their work achieved is recognized today as mathematical genetics, that branch of genetics whose aim is to investigate the laws governing the genetic structure of natural populations and, consequently, to clarify the mechanisms of evolution. For the benefit of population geneticists without advanced mathematical training, Professors Kimura and Ohta use verbal description rather than mathematical symbolism wherever practicable. A mathematical appendix is included.
This book is dedicated to those who died of malignant hyperthermia and to their families. It contains cases studies that would be helpful for anesthesiologists, surgeons, physiologists, molecular biologists, biophysicists, biochemists, pathologists, students, and post doctoral fellows.
Cellular Membrane: A Key to Disease Processes focuses on cellular membranes as a key to unlocking important new information about the pathological processes of strokes, heart attacks, diabetes, cancer, and other major diseases. The clinical relevance of basic research is particularly emphasized. Topics include calcium ions and calcium channel blockers, membrane ion channels and diabetes, membrane perturbation by asbestos fibers and disease, membrane receptors and signal transduction in tumor cells, anti-HIV compounds with membrane oriented specificity, and neuroleptic malignant syndrome. Cellular Membrane: A Key to Disease Processes is filled with illustrations, schemes, exciting ideas, and provocative hypotheses that are bound to lead to the development of new pharmacological techniques. It will prove to be an excellent reference guide for cell biologists and pathologists.
Central nervous system trauma, which encompasses stroke, subarachnoid hemorrhage, head injury, and spinal cord injury, is a leading cause of death in developed countries. In the search for underlying mechanisms, membrane involvement has been the common link. This fourth volume in the Membrane-Linked Diseases series is therefore dedicated to research on CNS trauma. Focusing on the mechanism of membrane damage, Central Nervous System Trauma: Research Techniques presents a variety of experimental techniques to study the mechanism of CNS trauma. Animal and tissue culture models provide the bulk of the research findings in this area. Possible pharmacological interventions are analyzed. This volume offers numerous illustrative examples, including full color figures. This book serves as a valuable resource for students and researchers, assisting in the comprehension of current trends in CNS trauma and helping to stimulate the discovery of new research areas.
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