Trace minerals and metals such as zinc, copper, and magnesium are accepted as a "natural" part of the human system. Interactions of some elements and/or disturbances in trace-metal or mineral homeostasis can, however, be toxic to the central nervous system (CNS). Mineral and Metal Neurotoxicology describes a wide range of basic and clinical issues
Trace minerals and metals such as zinc, copper, and magnesium are accepted as a "natural" part of the human system. Interactions of some elements and/or disturbances in trace-metal or mineral homeostasis can, however, be toxic to the central nervous system (CNS). Mineral and Metal Neurotoxicology describes a wide range of basic and clinical issues
Diet and Health examines the many complex issues concerning diet and its role in increasing or decreasing the risk of chronic disease. It proposes dietary recommendations for reducing the risk of the major diseases and causes of death today: atherosclerotic cardiovascular diseases (including heart attack and stroke), cancer, high blood pressure, obesity, osteoporosis, diabetes mellitus, liver disease, and dental caries.
Over 400 years ago, Swiss alchemist and physician Paracelsus (1493-1541) cited: "All substances are poisons; there is none that is not a poison. The right dose differentiates a poison from a remedy." This is often condensed to: "The dose makes the poison." So, why are we overtly anxious about intoxications?In fact, poisons became a global problem with the industrial revolution. Pesticides, asbestos, occupational chemicals, air pollution, and heavy metal toxicity maintain high priority worldwide, especially in developing countries. Children between 0 and 5 years old are the most vulnerable to both acute and chronic poisonings, while older adults suffer from the chronic effects of chemicals. This book aims to raise awareness about the challenges of poisons, to help clinicians understand current issues in toxicology.
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.
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.
Assembles international authorities to address contemporary research in metal neurotoxicity. Essential and non-essential metals play an important role in neurodevelopmental and neurodegenerative diseases. Recent developments in understanding the role of metals in the etiology of these disorders have led to rapid growth in clarifying the pathology of some of the most devastating diseases we face and in identifying potential new therapies. Few books or periodicals have been wholly dedicated to the topic of metals, and this collection is intended to serve as a resource for all researchers interested in metals and their role in health and disease.
Neurotoxicology is a broad and burgeoning field of research. Its growth in recent years can be related, in part, to increased interest in and concern with the fact that a growing number of anthropogenic agents with neurotoxic potential, including pesticides, lead, mercury, and the polytypic bypro ducts of combustion and industrial production, continue to be spewed into and accumulate in the environment. In addition, there is great interest in natural products, including toxins, as sources of therapeutic agents. Indeed, it is well known that many natural toxins of broadly differing structure, produced or accumulated for predatory or defensive purposes, and toxic agents, accumulated incidentally by numerous species, function to perturb nervous tissue. Components of some of these toxins have been shown to be useful therapeutic agents and/or research reagents. Unfor tunately, the environmental accumulation of some neurotoxic ants of anthropogenic ori gin, especially pesticides and metals, has resulted in incidents of human poisoning, some of epidemic proportion, and high levels of morbidity and mortality. Furthermore, an increasing incidence of neurobehavioral disorders, some with baffling symptoms, is confronting clinicians. It is not clear whether this is merely the result of increased vigi lance and/or improved diagnostics or a consequence of improved health care. In any case, the role of exposure to environmental and occupational neurotoxic ants in the etiology of these phenomena, as well as neurodegenerative diseases, is coming under increasing scrutiny and investigation.
Handbook of Developmental Neurotoxicology, Second Edition, provides a comprehensive view of the fundamental aspects of neurodevelopment, the pathways and agents that affect them, relevant clinical syndromes, and risk assessment procedures for developmental neurotoxicants. The editors and chapter authors are internationally recognized experts whose collaboration heralds a remarkable advance in the field, bridging developmental neuroscience with the principles of neurotoxicology. The book features eight new chapters with newly recruited authors, making it an essential text for students and professionals in toxicology, neurotoxicology, developmental biology, pharmacology, and neuroscience. - Presents a comprehensive, up-to-date resource on developmental neurotoxicology with updated chapters from the first edition - Contains new chapters that focus on subjects recent to the field - Includes well-illustrated material, with diagrams, charts, and tables - Contains compelling case studies and chapters written by world experts
