Download Free Metal Based Neurodegeneration Book in PDF and EPUB Free Download. You can read online Metal Based Neurodegeneration and write the review.

This exciting new book opens a window into the causes ofdebilitating neurological disorders such as Parkinson’sdisease, CJD and Huntington’s disease, and gives indicationsof the prospects for therapy, based on the understanding ofmolecular defects involved in these diseases. Looking at each specific neurological disorder in turn, the bookoutlines the role of metals in human biology, in particular in thebrain and explores tools for testing potential therapeuticstrategies. It concludes with an overview of the potential of bothchelation and antioxidant therapy and outlines some perspectivesfor the future.
Numerous studies have established a clear connection between neuronal oxidative stress and several neurodegenerative diseases, with consequential damages to lipids, proteins, nucleic acids, etc. In addition, several modifications indicative of oxidative stress have been described in association with neurons, neurofibrillary tangles and senile plaques in Alzheimer''s disease, including advanced glycation end products and free carbonyl oxidation. Oxidative damage and antioxidant responses are now well characterized, but sources of damaging free radicals are yet to be fully understood. Evidences of alteration in metal ions metabolism have been reported in various diseases like Alzheimer''s, Wilson, Menkes, Prion, Pick, Huntington disease, epilepsy and other pathological events. Thus, metal ions play a pivotal role in neurodegenerative phenomena. Chelation therapy is still in the early days of its development, but research in this area could lead to new products that could revolutionize treatment. Two international conferences on OC Metals and the Brain: From Neurochemistry to NeurodegenerationOCO (Padova, Italy, 2000 and Fez, Morocco, 2002) were recently held to discuss the role of metal ions in neurophysiopathology. A third will be held in 2005 in Johannesburg, South Africa. This book follows the same train of thought as those conferences, in order to highlight the unquestionable importance of metal ions in the research on the neurophysiopathology of neurodegenerative diseases. The excellent reputation of the scientists who have contributed to this project ensures the quality of the chapters presented here, and hopefully this will help spur new research initiatives in the field, which is still in its infancy. Contents: Metal-Catalyzed Redox Activity in Neurodegenerative Disease (M A Taddeo et al.); Aluminum and Central Nervous System Morphology in Hemodialysis (E Reusche); Transition Metals, Oxidation, Lipoproteins, and Amyloid-: Major Players in Alzheimer''s Disease (A Kontush); Molecular Basis of Copper Transport: Cellular and Physiological Functions of Menkes and Wilson Disease Proteins (ATP7A and ATP7B) (D R Kramer et al.); Copper-Zinc Superoxide Dismutase and Familial Amyotrophic Lateral Sclerosis (M B Yim et al.); Copper and Prion Disease (J Sasson & D Brown); Metallothioneins in Neurodegeneration (M Aschner et al.); Iron and Neurodegeneration (S L Grab & J R Connor); Iron, Neuromelanin, and -Synuclein in Neuropathogenesis of Parkinson''s Disease (K L Double et al.); Iron and Epilepsy (W-Y Ong et al.); Role of Iron Metabolism in Multiple Sclerosis (M J Kotze et al.); Neuroprotective Effects of Lithium (S Ermidiou-Pollet & S Pollet); and other articles. Readership: Academics, graduate students and researchers in neurology, psychiatry, neuroscience and environmental health."
This issue reviews the role of metals in neurodegenerative diseases; including Parkinson's and Huntington's disease; restless leg syndrome and NBIA disorders; and Wilson's disease and manganese and calcium accumulation disorders. An update on advances in neuroimaging and pathology of metal related disease is also presented.
Biometals such as copper, zinc and iron have key biological functions, however, aberrant metabolism can lead to detrimental effects on cell function and survival. These biometals have important roles in the brain, driving cellular respiration, antioxidant activity, intracellular signaling and many additional structural and enzymatic functions. There is now considerable evidence that abnormal biometal homeostasis is a key feature of many neurodegenerative diseases and may have an important role in the onset and progression of disorders such as Alzheimer’s, Parkinson’s, prion and motor neuron diseases. Recent studies also support biometal roles in a number of less common neurodegenerative disorders. The role of biometals in a growing list of brain disorders is supported by evidence from a wide range of sources including molecular genetics, biochemical studies and biometal imaging. These studies have spurred a growing interest in understanding the role of biometals in brain function and disease as well as the development of therapeutic approaches that may be able to restore the altered biometal chemistry of the brain. These approaches range from genetic manipulation of biometal transport to chelation of excess metals or delivery of metals where levels are deficient. A number of these approaches are offering promising results in cellular and animal models of neurodegeneration with successful translation to pre-clinical and clinical trials. At a time of aging populations and slow progress in development of neurotherapeutics to treat age-related neurodegenerative diseases, there is now a critical need to further our understanding of biometals in neurodegeneration. This issue covers a broad range of topics related to biometals and their role in neurodegeneration. It is hoped that this will inspire greater discussion and exchange of ideas in this crucial area of research and lead to positive outcomes for sufferers of these neurodegenerative diseases.
Numerous studies have established a clear connection between neuronal oxidative stress and several neurodegenerative diseases, with consequential damages to lipids, proteins, nucleic acids, etc. In addition, several modifications indicative of oxidative stress have been described in association with neurons, neurofibrillary tangles and senile plaques in Alzheimer's disease, including advanced glycation end products and free carbonyl oxidation.Oxidative damage and antioxidant responses are now well characterized, but sources of damaging free radicals are yet to be fully understood. Evidences of alteration in metal ions metabolism have been reported in various diseases like Alzheimer's, Wilson, Menkes, Prion, Pick, Huntington disease, epilepsy and other pathological events. Thus, metal ions play a pivotal role in neurodegenerative phenomena.Chelation therapy is still in the early days of its development, but research in this area could lead to new products that could revolutionize treatment. Two international conferences on “Metals and the Brain: From Neurochemistry to Neurodegeneration” (Padova, Italy, 2000 and Fez, Morocco, 2002) were recently held to discuss the role of metal ions in neurophysiopathology. A third will be held in 2005 in Johannesburg, South Africa.This book follows the same train of thought as those conferences, in order to highlight the unquestionable importance of metal ions in the research on the neurophysiopathology of neurodegenerative diseases. The excellent reputation of the scientists who have contributed to this project ensures the quality of the chapters presented here, and hopefully this will help spur new research initiatives in the field, which is still in its infancy.
Bioinorganic chemistry has a cross disciplinary approach, applying the principles of chemistry to biological systems. Metallochemistry of Neurodegeneration: Biological, Chemical and Genetic Aspects discusses the rapidly developing area of metals in the nervous system and their role in neurodegenerative disease, such as Alzheimer's, Parkinson's and prion diseases. Written by leading experts in their fields, each chapter combines elements of genetics, biochemistry and biological inorganic chemistry in its discussion. The book highlights the differences in pathologies of neurodegenerative diseases but also discusses the mechanistic similarities. Sections include: metal ions and prion diseases; metal ions and Alzheimer disease; manganese in brain functioning; metal involvement in Parkinson disease; Cu-Zn superoxide dismutase and familial amyotrophic lateral sclerosis. This book will appeal to both chemists and biologists at the post graduate and research level.
This eBook is a collection of articles from a Frontiers Research Topic. Frontiers Research Topics are very popular trademarks of the Frontiers Journals Series: they are collections of at least ten articles, all centered on a particular subject. With their unique mix of varied contributions from Original Research to Review Articles, Frontiers Research Topics unify the most influential researchers, the latest key findings and historical advances in a hot research area! Find out more on how to host your own Frontiers Research Topic or contribute to one as an author by contacting the Frontiers Editorial Office: frontiersin.org/about/contact.
About the Series... Metal Ions in Life Sciences links coordination chemistry and biochemistry in their widest sense and thus increases our understanding of the relationship between the chemistry of metals and life processes. The series reflects the interdisciplinary nature of Biological Inorganic Chemistry and coordinates the efforts of scientists in fields like biochemistry, inorganic chemistry, coordination chemistry, molecular and structural biology, enzymology, environmental chemistry, physiology, toxicology, biophysics, pharmacy, and medicine. Consequently, the volumes are an essential source for researchers active in these and related fields as well as teachers preparing courses, e.g., in Bioinorganic Chemistry. About this Book... Volume 1, devoted solely to the vital research area concerning the role of metal ions in neurodegenerative diseases, offers in 15 stimulating chapters an authoritative and timely view of this fascinating subject. Written by 41 internationally recognized experts, Neurodegenerative Diseases and Metal Ions highlights, supported by 130 illustrations, the recent progress made in understanding the role metal ions play in diseases like transmissible spongiform encephalopathies (Creutzfeldt-Jakob and related diseases), Alzheimer's, Parkinson's, Huntington's, Wilson's and Menkes' diseases, as well as in familial amyotrophic lateral sclerosis and others. The interplay between metal ions, catecholamines and the formation of reactive oxygen species resulting in oxidative stress is considered, as is the metalloneurochemistry of zinc and the neurotoxicity of aluminum, cadmium, lead, and mercury. The need for novel drugs which manipulate metal-centered neuropathology is emphasized.
Biometals in Neurodegenerative Diseases: Mechanisms and Therapeutics is an authoritative and timely resource bringing together the major findings in the field for ease of access to those working in the field or with an interest in metals and their role in brain function, disease, and as therapeutic targets. Chapters cover metals in Alzheimer’s Disease, Parkinson’s Disease, Motor Neuron Disease, Autism and lysosomal storage disorders. This book is written for academic researchers, clinicians and advanced graduate students studying or treating patients in neurodegeneration, neurochemistry, neurology and neurotoxicology. The scientific literature in this field is advancing rapidly, with approximately 300 publications per year adding to our knowledge of how biometals contribute to neurodegenerative diseases. Despite this rapid increase in our understanding of biometals in brain disease, the fields of biomedicine and neuroscience have often overlooked this information. The need to bring the research on biometals in neurodegeneration to the forefront of biomedical research is essential in order to understand neurodegenerative disease processes and develop effective therapeutics. Authoritative and timely resource bringing together the major findings in the field for those with an interest in metals and their role in the brain function, disease, and as therapeutic targets Written for academic researchers, clinicians, and advanced graduate students studying, or treating, patients in neurodegeneration, neurochemistry, neurology and neurotoxicology Edited by international leaders in the field who have contributed greatly to the study of metals in neurodegenerative diseases
Since Alois Alzheimer described the results of his postmortem studies in 1906, significant strides have been made in understanding the pathogenesis of neurodegenerative diseases. Substantial evidence has accumulated indicating that diverse neurodegenerative disorders might share a common pathological mechanism: the misfolding, aggregation and accumulation of proteins (termed "amyloid") in the brain. Metal ions have long been thought to catalyze protein misfolding initiating a cascade of events resulting in oxidative damage and neurodegeneration. They have, consequently, been seen as a suitable pharmacological target. However, drugs aimed at simply removing excess metals or interfering in amyloid deposition were unsuccessful and scientists have been forced to review the classical hypothesis. The latest advances suggest that deficiencies in protein homeostasis may lead to cell dysfunction and disease. Furthermore, small molecules with the potential to control metal homeostasis, or metallostasis, are expected to provide the framework for the design of novel proteostasis regulators. This book provides an up-date on the latest developments in this fast moving field. Traditional views concerning the relationship between the physio-pathological cycles of copper, zinc, iron, aluminium and the evolution of life, are compared with emerging ideas in the neuroscience of metal ions. Topics covered emphasize the importance of metals and oxidation chemistry to neuroscientists as well as providing a wider, multidisciplinary background to chemists who are attracted by these fascinating subjects. The text starts with a chapter on chemical evolution, the brain and metallomics which describes the brain's natural defences to adverse conditions. It then goes on to cover the chemistry and biology of proteostasis, environmental factors, and the role played by membranes in protein misfolding. The remaining chapters cover the role of metals and oxidative stress in Alzheimer's Disease, Parkinsonism, ALS and other neurodegenerative diseases. The book is suitable for academics, those working in industry, and postgraduate students.