Human Blood Tissue Intrinsic Bioelectromagnetic Energy Transferring Onto a Miniorgan | Chapter 14 | Issues and Developments in Medicine and Medical Research Vol. 8

 Human hair is made up of a follicle (also known as a root) that penetrates the skin and an outer skin component known as the shaft. Hair follicles have been defined as microorganisms with their own cell divisions, ageing stages, and the ability to emit electromagnetic radiation. The goal of this paper is to show evidence of human inter-tissue electromagnetic energy transmission through a glass slide, namely from human blood tissue to the previously described miniorgan or follicle, using in vitro experiments. Organs like the brain and heart have been discovered to emit bioelectrical signals that can currently be exhibited by instruments due to their intrinsic biomagnetism.

The mechanism behind this new discovery was made feasible by the advent in 2015 of a tabletop optical microscope approach for displaying electromagnetic energy emissions from plants and animals. The described property of anisotropic crystals of 100% absorption of incoming electromagnetic radiation waves by Potassium Ferricyanide (K3Fe), an anisotropic crystal, is critical to the current discovery. A single layer human blood smear, for example, was sandwiched between two glass slides (SDW). A freshly plucked in toto human hair was then covered by drops of diluted K3Fe on the top slide of the SDW. The electromagnetic waves generated by the hair follicle had frequently triggered ordered semicircular periodic crystals of K3Fe in control studies. This author's previous research has shown a "bioelectromagnetic cross-talk" between the follicle and the blood. This was observed when the follicle came into physical touch with blood drops on a glass slide. The blood tissue energy is transmitted through a 1 mm glass barrier in the current tests, thus there is no direct tissue contact. Bioelectromagnetic Fields (BEMFs) energy from human blood is introduced into a miniorgan in the data shown here. This energy may be seen breaking through a 1 mm glass slide barrier. To analyse the physiological implications of human blood tissue as a molecular and BEMFs energy source, more research is needed.

Author(S) Details

Abrahám A. Embí
13442 SW 102 Lane, Miami Florida, USA.

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