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EVIDENCE OF HUMAN INTER-TISSUE BIOELECTROMAGNETIC TRANSFER: THE HUMAN BLOOD TISSUE INTRINSIC BIOELECTROMAGNETIC ENERGY TRANSFERRING ONTO A MINIORGAN

Journal: INTERNATIONAL JOURNAL OF RESEARCH -GRANTHAALAYAH (Vol.8, No. 8)

Publication Date:

Authors : ;

Page : 288-296

Keywords : Human Blood Bioelectromagmetism; Human Follicle; Bioelectromagnetism; Inter Tissue Bioelectromagnetic; Energy Transfer; Body Parts Energy Exchange; Electromagnetic Radiation; Absortion; Potassium Ferricyanide; Anisotropic Crystal;

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Abstract

Basically,the human hair consists of a follicle a.k.a root penetrating the skin and an outer skin structure commonly called the shaft. The hair follicle has been classified as a miniorgan having its own cells divisions; aging stages and also demonstrated to emit electromagnetic radiation. The intent of this manuscript is to demonstrate via in vitro experiments evidence of human inter-tissue electromagnetic energy transfer through a glass slide, namely from human blood tissue to the previously described miniorgan or follicle. The mechanism behind this new finding was possible due to the introduction in 2015 of a tabletop optical microscopy method designed to display plants and animal tissue electromagnetic energy emissions. Essential to present finding is the described property of anisotropic crystals of full absorption of incoming electromagnetic radiation waves. K3Fe is an anisotropic crystal. For example, a single layer human blood smear was sandwiched (SDW) by a second glass slide. On the top slide of the SDW, a freshly plucked in toto human hair was then covered by drops diluted K3Fe. Control experiments had repeatedly shown orderly semicircular periodic crystals of K3Fe triggered by the electromagnetic waves emitted by the hair follicle. Prior experiments by this author, have hinted at a “bioelectromagnetic cross-talk” between the follicle and blood. This was seen when there was physical contact between the follicle and blood drops on a glass slide. In the present experiments there is no direct tissue contact, the energy is transmitted through a 1 mm glass barrier. The data herein presented introduces Bioelectromagnetic Fields (BEMFs) energy from human blood onto a miniorgan. This energy is shown penetrating a 1 mm glass slide barrier. Further research is warranted to assess the physiological implications of the human blood tissue as a molecular and BEMFs energy source.

Last modified: 2020-09-15 18:55:46