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Ischemia. --- Cerebral ischemia. --- Spinal cord --- Wounds and injuries. --- Brain ischemia --- Cerebrovascular disease --- Ischemia --- Ischaemia --- Blood circulation disorders
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Ischemia. --- Arteriosclerosis. --- Efferent pathways. --- Motor nervous system --- Motor pathways --- Motor tracts --- Arterial sclerosis --- Arteries --- Hardening of the arteries --- Sclerosis, Arterial --- Ischaemia --- Hardening --- Sclerosis --- Central nervous system --- Arterial occlusions --- Blood circulation disorders --- Ischemia --- Arteriosclerosis --- Efferent Pathwayx --- Neovascularization, Physiologic --- therapy --- Ischemia - therapy --- Arteriosclerosis - therapy
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Reperfusion injury --- Ischemia. --- Immunosuppressive agents. --- Pathophysiology. --- Myocardial Reperfusion Injury --- Fingolimod Hydrochloride --- Myocardial Ischemia. --- physiopathology. --- therapeutic use. --- Heart Disease, Ischemic --- Ischemia, Myocardial --- Ischemic Heart Disease --- Disease, Ischemic Heart --- Diseases, Ischemic Heart --- Heart Diseases, Ischemic --- Ischemias, Myocardial --- Ischemic Heart Diseases --- Myocardial Ischemias --- Immunosuppressant agents --- Immunosuppressants --- Immunosuppressive drugs --- Drugs --- Immunopharmacology --- Ischaemia --- Blood circulation disorders --- Injury, Reperfusion --- Ischemia
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Brain Hypoxia and Ischemia Gabriel G. Haddad, M.D. and Shan Ping Yu, M.D., Ph.D., Editors Brain Hypoxia and Ischemia explores the various aspects of cell death and survival that are crucial for understanding the basic mechanisms underlying brain hypoxia and ischemia. Chapters focus on a panorama of issues including the role of ion channels/transporters, mitochondria and apoptotic mechanisms, the roles of glutamate/NMDA, mechanisms in penumbral cells and the importance of intermittent hypoxia and gene regulation under these stressful conditions. The volume explores findings from both mammalian and invertebrate model systems and their applicability to human systems and diseases. Careful consideration is also given to differences in hypoxia and ischemia across development. This volume aims to increase the understanding of these mechanisms and to stimulate research on better diagnosis and treatment of diseases that afflict the brain and potentially other organs when O2 levels are dysregulated. Brain Hypoxia and Ischemia is designed for neuroscientists, clinicians and medical/graduate students for use in both basic research and clinical practice. Gabriel G. Haddad, M.D. is Professor of Pediatrics and Neuroscience and Chair of the Department of Pediatrics at the University of California, San Diego. He is also Physician-in-Chief at Rady Children’s Hospital in San Diego. Shan Ping Yu, M.D., Ph.D. is Professor of Anesthesiology at Emory University in Atlanta, GA.
Cerebral anoxia. --- Cerebral ischemia. --- Cerebral anoxia --- Cerebral ischemia --- Brain Diseases --- Cerebrovascular Disorders --- Brain Ischemia --- Hypoxia, Brain --- Central Nervous System Diseases --- Vascular Diseases --- Nervous System Diseases --- Cardiovascular Diseases --- Diseases --- Human Anatomy & Physiology --- Medicine --- Neuroscience --- Neurology --- Health & Biological Sciences --- Ischemia. --- Ischaemia --- Anoxia, Cerebral --- Brain anoxia --- Brain hypoxia --- Hypoxia cerebral --- Medicine. --- Human physiology. --- Neurosciences. --- Neurology. --- Neurobiology. --- Biomedicine. --- Human Physiology. --- Blood circulation disorders --- Anoxemia --- Cerebrovascular disease --- Neurosciences --- Nervous system --- Neuropsychiatry --- Human biology --- Medical sciences --- Physiology --- Human body --- Neural sciences --- Neurological sciences --- Neurology .
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Ischemia and Loss of Vascular Autoregulation in Ocular and Cerebral Diseases: A New Perspective presents evidence that ischemia and loss of autoregulation of blood flow are associated with the onset of the major ocular and cerebral diseases including macular degeneration, diabetic retinopathy, low and normal tension open angle glaucoma, stroke and Alzheimer’s disease. Recognition of these vascular changes underline the critical need for clinicians to monitor blood flow and autoregulation to improve early diagnosis and to optimize therapies of ocular and cerebral vascular diseases. The text brings to clinicians in Ophthalmology, Neurology, Medicine, Optometry and Geriatrics decisive guidance on the practical aspects for early diagnosis and treatment of ocular and cerebral diseases. The author brings together in a concise form the progress made over the span of his career and provides new perspectives and understanding of the fluid circulations of the eye and the brain. In addition, he explains the new analytical technologies that made the new concepts possible. The physiological and functional importance of blood flow autoregulation in the eye and in the brain in minimizing the progression of pathology, including the ischemia resulting from stenosis of the internal carotid artery and stroke, are also presented . ABOUT THE AUTHOR: Dr. Langham was born in London, England. In 1947, he joined the Ophthalmological Research Unit, newly formed by the Medical Research Council of the United Kingdom under the direction of Sir Stewart Duke-Elder. In 1956, the author enjoyed a research fellowship at Harvard University. After returning to England for a time, he accepted a position of Associate Professor of Ophthalmology and Director of Research at the Wilmer Ophthalmological Institute of the Johns Hopkins Hospital and Medical school in 1959. There he initiated a program in which all residents spent time engaged in research. This productive interaction between the disciplines led to many important clinical diagnostic and therapeutic advances.
Bifurcation theory. --- Differential equations, Partial --Numerical solutions. --- Representations of groups. --- Differential equations, Partial --- Bifurcation theory --- Representations of groups --- Ischemia --- Homeostasis --- Eye --- Regional Blood Flow --- Peripheral Vascular Diseases --- Intraocular Pressure --- Face --- Blood Circulation --- Pathologic Processes --- Vascular Diseases --- Sense Organs --- Physiological Processes --- Ocular Physiological Phenomena --- Phenomena and Processes --- Cardiovascular Diseases --- Anatomy --- Head --- Physiological Phenomena --- Pathological Conditions, Signs and Symptoms --- Cardiovascular Physiological Processes --- Cardiovascular Physiological Phenomena --- Body Regions --- Diseases --- Circulatory and Respiratory Physiological Phenomena --- Calculus --- Ophthalmology & Optometry --- Mathematical Theory --- Pathology --- Medicine --- Mathematics --- Physical Sciences & Mathematics --- Health & Biological Sciences --- Numerical solutions --- Ischemia. --- Peripheral vascular diseases --- Cerebral ischemia. --- Blood-vessels --- Diseases. --- Diagnosis. --- Ischaemia --- Brain ischemia --- Chevalley groups. --- Medicine. --- Angiology. --- Neurology. --- Ophthalmology. --- Medicine & Public Health. --- Biomedicine general. --- Group theory --- Differential geometry. Global analysis --- Cerebrovascular disease --- Blood circulation disorders --- Numerical solutions. --- Finite groups. --- Angiography. --- Diagnosis, Radioscopic --- Radiography, Medical --- Clinical sciences --- Medical profession --- Human biology --- Life sciences --- Medical sciences --- Physicians --- Nervous system --- Neuropsychiatry --- Radiography --- Neurology . --- Biomedicine, general. --- Health Workforce --- Groupes algébriques linéaires --- Groupes algébriques linéaires --- Représentations de groupes --- Equations aux derivees partielles --- Bifurcations --- Colloque
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