Biological transmutation has been postulated by several groups of workers in microbial systems. Quantizing structures of optimal size and shape are necessary for non barrier nuclear interactions. The situation is realized in microbial cultures. During the growth process, the replication of DNA and other biomacromolecules takes place. In the region of growth, the interatomic potential holes with slowly changing sizes are constantly appearing and in this situation non barrier nuclear interactions can take place. Actinidic archaea has been described in human systems from our laboratory and function as cellular endosymbionts regulating multiple cellular functions. The actinidic archaea utilizes an alternate biochemistry depended on actinides for enzyme catalysis. The seashores of Kerala are rich in actinidic elements present as rutile, illmenite and monazite. The actinidic archaea is an endosymbiont of the human cell and it is possible that the organism can mediate biological transmutation. Transmutation of magnesium to calcium can serve as a mechanism of regulation of the neuro-immuno-endocrine system. Deficiency of magnesium is seen in degenerations, malignancy, metabolic syndrome x, psychiatric disorders and immune disease. The actinidic archaea can exist as nanoarchaea which can undergo magnetite and calcium mineralization. It is possible that magnesium is being transmuted biologically to calcium to produce amounts sufficient for calcium mineralization. Calcified nanoarchaea can produce a systemic immune activation contributing to the diverse pathologies of degenerations, malignancy, metabolic syndrome x, psychiatric disorders and immune disease to study biological transmutation of magnesium to calcium and cerium.
| The Full Book PDF |
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| Front Matter |
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| Chapter 1 Actinidic Archaea Mediates Biological Transmutation in Human Systems - Experimental Evidence |
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| Chapter 2 Copper Zinc Transmutation and Brain Function |
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| Chapter 3 Porphyrions, the Internet and Mind - Role of Porphyrins in Environmental Communication/Modulation of Digital Information Storage/Processing System |
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| Chapter 4 Membrane Sodium Potassium ATPase Inhibition Mediated ATP Synthesis Induced by Digoxin, Photoinduction and Electromagnetic Fields |
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| Chapter 5 Endosymbiotic Actinidic Archaeal Digoxin Inhibited Sodium Potassium ATPase Mediated ATP Synthesis and Archaeal Ectoatpases Produce Neuro-Immuno-Metabolic-Endrocrine/Cell Cycle Regulation |
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| Chapter 6 Endosymbiotic Actinidic Archaea/Viroids, Quantal Perception and Biological Reincarnation |
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| Chapter 7 Archaeal Digoxin and Creation of Cellular Plasma State - Molecular/Cellular Electromagnetic Signal Transduction |
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| Back Matter |
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Ravikumar Kurup
Dr. Ravikumar Kurup trained in Internal Medicine, Neurology and Metabolic Medicine at Medical College, Trivandrum and Christian Medical College, Vellore. He holds a doctorate degree in Internal Medicine and Neurology. He is a member of the National Academy of Medical Sciences, India. He works as Professor of Metabolic Medicine and Metabolic Neurology at Metabolic Disorders Research Center, Trivandrum. He also works as Professor of Internal Medicine and Head of the divisions of Metabolic Medicine and Hematology at Medical College Hospital, Trivandrum. His areas of research interests are in Neurochemistry and Metabolic Medicine.
Parameswara Achutha Kurup
The Metabolic Disorders Research Centre, TC 4/1525, Gouri Sadan, Kattu Road North of Cliff House, Kowdiar PO Trivandrum, Kerala, India.
Experts in Neurology, Psychiatry, Philosophy, Physics
