Deuterium is a heavy isotope of hydrogen,with an extra neutron,endowing it with unique biophysical and biochemical properties compared to hydrogen.The ATPase pumps in the mitochondria depend upon proton motive force t...Deuterium is a heavy isotope of hydrogen,with an extra neutron,endowing it with unique biophysical and biochemical properties compared to hydrogen.The ATPase pumps in the mitochondria depend upon proton motive force to catalyze the reaction that produces ATP.Deuterons disrupt the pumps,inducing excessive reactive oxygen species and decreased ATP synthesis.The aim of this review is to develop a theory that mitochondrial dysfunction due to deuterium overload,systemically,is a primary cause of Parkinson’s disease(PD).The gut microbes supply deuterium-depleted short chain fatty acids(SCFAs)to the colonocytes,particularly butyrate,and an insufficient supply of butyrate may be a primary driver behind mitochondrial dysfunction in the gut,an early factor in PD.Indeed,low gut butyrate is a characteristic feature of PD.Mitochondrial dysfunction is a factor in many diseases,including all neurodegenerative diseases.Biological organisms have devised sophisticated strategies for protecting the ATPase pumps from deuterium overload.One such strategy may involve capturing deuterons in bis-allylic carbon atoms present in polyunsaturated fatty acids(PUFAs)in cardiolipin.Cardiolipin uniquely localizes to the inner membrane of the intermembrane space,tightly integrated into ATPase proteins.Bis-allylic carbon atoms can capture and retain deuterium,and,interestingly,deuterium doping in PUFAs can quench the chain reaction that causes massive damage upon lipid peroxidation.Neuronal cardiolipin is especially rich in docosahexaenoic acid(DHA),a PUFA with five bisallylic carbon atoms.Upon excessive oxidative stress,cardiolipin migrates to the outer membrane,where it interacts withα-synuclein(α-syn),the amyloidogenic protein that accumulates as fibrils in Lewy bodies in association with PD.Such interaction leads to pore formation and the launch of an apoptotic cascade.α-syn misfolding likely begins in the gut,and misfoldedα-syn travels along nerve fibers,particularly the vagus nerve,to reach the brainstem nuclei,where it can seed misfolding ofα-syn molecules already present there.Mitochondrial dysfunction in the gut may be a primary factor in PD,and low-deuterium nutrients may be therapeutic.展开更多
Many neurological diseases, including autism, depression, dementia, anxiety disorder and Parkinson’s disease, are associated with abnormal sleep patterns, which are directly linked to pineal gland dysfunction. The pi...Many neurological diseases, including autism, depression, dementia, anxiety disorder and Parkinson’s disease, are associated with abnormal sleep patterns, which are directly linked to pineal gland dysfunction. The pineal gland is highly susceptible to environmental toxicants. Two pervasive substances in modern industrialized nations are aluminum and glyphosate, the active ingredient in the herbicide, Roundup?. In this paper, we show how these two toxicants work synergistically to induce neurological damage. Glyphosate disrupts gut bacteria, leading to an overgrowth of Clostridium difficile. Its toxic product, p-cresol, is linked to autism in both human and mouse models. p-Cresol enhances uptake of aluminum via transferrin. Anemia, a result of both aluminum disruption of heme and impaired heme synthesis by glyphosate, leads to hypoxia, which induces increased pineal gland transferrin synthesis. Premature birth is associated with hypoxic stress and with substantial increased risk to the subsequent development of autism, linking hypoxia to autism. Glyphosate chelates aluminum, allowing ingested aluminum to bypass the gut barrier. This leads to anemia-induced hypoxia, promoting neurotoxicity and damaging the pineal gland. Both glyphosate and aluminum disrupt cytochrome P450 enzymes, which are involved in melatonin metabolism. Furthermore, melatonin is derived from tryptophan, whose synthesis in plants and microbes is blocked by glyphosate. We also demonstrate a plausible role for vitamin D3 dysbiosis in impaired gut function and impaired serotonin synthesis. This paper proposes that impaired sulfate supply to the brain mediates the damage induced by the synergistic action of aluminum and glyphosate on the pineal gland and related midbrain nuclei.展开更多
An analysis of selected datasets from the FDA’s drug Adverse Event Reporting System (FAERS) leads us to hypothesize that glyphosate contamination in both food and drugs is a major contributor to chronic and acute kid...An analysis of selected datasets from the FDA’s drug Adverse Event Reporting System (FAERS) leads us to hypothesize that glyphosate contamination in both food and drugs is a major contributor to chronic and acute kidney failure respectively. In chronic kidney failure, glyphosate-induced pancreatitis results in the release of trypsin, causing a leaky vasculature. The albumin-bound glyphosate escapes into the tissues, protecting the circulatory system and kidneys but resulting in multiple symptoms related to skin, gut, brain, bones, lungs, etc. The rare and poorly understood acute kidney failure response reported for protamine sulfate and Trasylol? is strikingly similar to that associated with glyphosate poisoning. Both drugs are derived from biological tissues that are plausibly contaminated with glyphosate. These drugs protect from haemorrhage, which leads to retention of glyphosate in the vasculature, are followed by circulatory collapse and a high likelihood of death as an outcome. We support our argument by comparing symptom profiles of selected subsets of FAERS with those related to glyphosate poisoning, anomalous reactions to protamine sulfate, and conditions showing strong statistical time-trend correlations with glyphosate.展开更多
基金funded in part by Quanta Computer,Inc.,in Tanyuan,Taiwan,under contract number 6950759,as part of the AIR project.
文摘Deuterium is a heavy isotope of hydrogen,with an extra neutron,endowing it with unique biophysical and biochemical properties compared to hydrogen.The ATPase pumps in the mitochondria depend upon proton motive force to catalyze the reaction that produces ATP.Deuterons disrupt the pumps,inducing excessive reactive oxygen species and decreased ATP synthesis.The aim of this review is to develop a theory that mitochondrial dysfunction due to deuterium overload,systemically,is a primary cause of Parkinson’s disease(PD).The gut microbes supply deuterium-depleted short chain fatty acids(SCFAs)to the colonocytes,particularly butyrate,and an insufficient supply of butyrate may be a primary driver behind mitochondrial dysfunction in the gut,an early factor in PD.Indeed,low gut butyrate is a characteristic feature of PD.Mitochondrial dysfunction is a factor in many diseases,including all neurodegenerative diseases.Biological organisms have devised sophisticated strategies for protecting the ATPase pumps from deuterium overload.One such strategy may involve capturing deuterons in bis-allylic carbon atoms present in polyunsaturated fatty acids(PUFAs)in cardiolipin.Cardiolipin uniquely localizes to the inner membrane of the intermembrane space,tightly integrated into ATPase proteins.Bis-allylic carbon atoms can capture and retain deuterium,and,interestingly,deuterium doping in PUFAs can quench the chain reaction that causes massive damage upon lipid peroxidation.Neuronal cardiolipin is especially rich in docosahexaenoic acid(DHA),a PUFA with five bisallylic carbon atoms.Upon excessive oxidative stress,cardiolipin migrates to the outer membrane,where it interacts withα-synuclein(α-syn),the amyloidogenic protein that accumulates as fibrils in Lewy bodies in association with PD.Such interaction leads to pore formation and the launch of an apoptotic cascade.α-syn misfolding likely begins in the gut,and misfoldedα-syn travels along nerve fibers,particularly the vagus nerve,to reach the brainstem nuclei,where it can seed misfolding ofα-syn molecules already present there.Mitochondrial dysfunction in the gut may be a primary factor in PD,and low-deuterium nutrients may be therapeutic.
文摘Many neurological diseases, including autism, depression, dementia, anxiety disorder and Parkinson’s disease, are associated with abnormal sleep patterns, which are directly linked to pineal gland dysfunction. The pineal gland is highly susceptible to environmental toxicants. Two pervasive substances in modern industrialized nations are aluminum and glyphosate, the active ingredient in the herbicide, Roundup?. In this paper, we show how these two toxicants work synergistically to induce neurological damage. Glyphosate disrupts gut bacteria, leading to an overgrowth of Clostridium difficile. Its toxic product, p-cresol, is linked to autism in both human and mouse models. p-Cresol enhances uptake of aluminum via transferrin. Anemia, a result of both aluminum disruption of heme and impaired heme synthesis by glyphosate, leads to hypoxia, which induces increased pineal gland transferrin synthesis. Premature birth is associated with hypoxic stress and with substantial increased risk to the subsequent development of autism, linking hypoxia to autism. Glyphosate chelates aluminum, allowing ingested aluminum to bypass the gut barrier. This leads to anemia-induced hypoxia, promoting neurotoxicity and damaging the pineal gland. Both glyphosate and aluminum disrupt cytochrome P450 enzymes, which are involved in melatonin metabolism. Furthermore, melatonin is derived from tryptophan, whose synthesis in plants and microbes is blocked by glyphosate. We also demonstrate a plausible role for vitamin D3 dysbiosis in impaired gut function and impaired serotonin synthesis. This paper proposes that impaired sulfate supply to the brain mediates the damage induced by the synergistic action of aluminum and glyphosate on the pineal gland and related midbrain nuclei.
文摘An analysis of selected datasets from the FDA’s drug Adverse Event Reporting System (FAERS) leads us to hypothesize that glyphosate contamination in both food and drugs is a major contributor to chronic and acute kidney failure respectively. In chronic kidney failure, glyphosate-induced pancreatitis results in the release of trypsin, causing a leaky vasculature. The albumin-bound glyphosate escapes into the tissues, protecting the circulatory system and kidneys but resulting in multiple symptoms related to skin, gut, brain, bones, lungs, etc. The rare and poorly understood acute kidney failure response reported for protamine sulfate and Trasylol? is strikingly similar to that associated with glyphosate poisoning. Both drugs are derived from biological tissues that are plausibly contaminated with glyphosate. These drugs protect from haemorrhage, which leads to retention of glyphosate in the vasculature, are followed by circulatory collapse and a high likelihood of death as an outcome. We support our argument by comparing symptom profiles of selected subsets of FAERS with those related to glyphosate poisoning, anomalous reactions to protamine sulfate, and conditions showing strong statistical time-trend correlations with glyphosate.
