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

© 2020 The Author(s). This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited. 288 EVIDENCE OF HUMAN INTER-TISSUE BIOELECTROMAGNETIC TRANSFER: THE HUMAN BLOOD TISSUE INTRINSIC BIOELECTROMAGNETIC ENERGY TRANSFERRING ONTO A MINIORGAN


INTRODUCTION
The purpose of this manuscript is to introduce documentation demonstrating the transfer of BEMFs energy from human connective tissue (blood) to a human mini-organ (hair follicle). The hair follicle has been classified as a miniorgan, thus exhibiting its own cells division molecular activity and metabolism [1]. The Bioelectromagnetic discipline was first documented by using a sensitive atomic magnetometer detecting BEMFs in living tissue [2]; and documented by using complex equipment [3]. In this manuscript a tabletop glass slide microscopy method introduced in 2015, has enabled for the documentation of BEMFs in plants and animal tissue [4], [5]; and expanded BEMFs experimentation with minimal equipment requirements. One paper in particular has relevancy to this manuscript and is the demonstration of hair follicles BEMFs penetrating glass barriers [6].

EVIDENCE OF BEMFS TRANSFER BETWEEN BLOOD AND AN ORGAN
In this manuscript, In Vitro experiments using optical microscopy will introduce evidence of BEMFs transfer between blood and hair follicles through a glass barrier. Results from in vitro experiments where a 1 mm glass slide barrier vertically separating blood and hair follicle will show evidence of BEMFs energy transfer between two tissues resulting in an increase in crystallization surrounding the follicle.

PREPARING THE SOLUTION
Commercially available bottled water was tested for impurities via a handheld electrical fields sensor (Lishtot Sensor). A solution was prepared by diluting ≅ 2 grams of Potassium Ferricyanide (K Fe3) in 2 ml of the previously tested for impurities bottled spring water. The solution placed inside a 6 inch 4 mm OD glass tube and withdrawn as needed via pipette.

THE SINGLE SIDE PREPARATION (SSP)
The SSP is an open-air technique where freshly plucked in toto scalp hairs were placed on a clean 25x75x1mm glass slide; and covered by a drop of K3Fe in solution; the drop was then allowed to evaporate. Prior to evaporation, the drop was then touched by a wooden toothpick and scattered as to cover the follicle and shaft (Fig 1).
After the hair sample in SSP is stabilized, meaning the hair sample can be moved and stay in place. A wooden toothpick us used to gently find an optimal position of the samples such as away from the drops edges.

The Sandwiched Blood Smear (SDW) Preparation
A finger stick allowed for the milking of two drops of blood, then placed on a clean 25x75x1mm glass slide. The mechanical smear was done as per published instructions from the USA center for disease control [7]. The smear was allowed to dry by keeping it uncovered and at room temperature for 5 minutes. The SSP slide (Fig 2) was then placed over the dry blood smear, thus creating a human blood SDW. The preparation was then allowed to evaporate in the dark by covering with one half of an empty microscope slide box. The average time for total evaporation is two hours, after which was placed on the video microscope-viewing field. Microphotographs and video recordings were obtained and downloaded into an Apple MacBook Pro computer Photo Application for further review.

EXTERNAL BEMFS ON CRYSTALLIZATION ADVANCE
The In Vitro experiments (n 12) of sandwiched (SDW) blood tissue showed several phenomena that could be contrasted with control experiments (n 25) as shown (Fig 3) below.

CONTROL EXPERIMENT WITHOUT BLOOD SMEAR
Figure below showing a control (No Blood smear in SDW) follicle in SSP K3Fe. The organized periodic BEMFs expressed as semicircular K3Fe crystals in front of the follicles can be appreciated (Fig 3) below.

EXPERIMENTS WITH SMEARED BLOOD TISSUE IN SDW
In the slide preparation below, the hair follicle emitted BEMFs have not yet being sensed by the KFe3 crystals (Fig 4). Notice the lack of delay in the crystallization advance during evaporation.

ENTERING THE OUTER EDGE OF FOLICLE BEMFS AND FULL ABSORPTION BY K3FE CRYSTALS
Once that threshold is entered the effect seen could be described as a temporary slowing of evaporation advance by the hair follicle intrinsic BEMFs on the evaporating K3Fe (Fig 5). Prior papers support full absorption of BEMFs by the anisotropic K3Fe crystals [8], [9]. As stated in the periodical Science Daily "Moscow Institute of Physics and Technology. (2016, January 14). New way to absorb electromagnetic radiation demonstrated: Scientists show that it is possible to fully absorb electromagnetic radiation using an anisotropic crystal. ScienceDaily. Retrieved August 28, 2020 www.sciencedaily.com/releases/2016/01/160114113524.htm This is documented in Figure 5 below, where once the BEMFs boundary of the hair follicle there are back and forth forces at play, thus delaying the crystallization advance.

ADDITIONAL EXPERIMENTS CONFIRMING EFFECT OF BEMFS BEING ABSORBED BY K3Fe
Again, in this manuscript once the KFe3 in solution had completely evaporated, there is an increase in crystals adhering to the hair follicles as shown in the following examples (Fig 6,7,8,9). This caused by the blood tissue transferring BEMFs energy through a 1 mm glass slide and absorbed by K3Fe crystals.

PRIOR DEMONSTRATION OF HAIR FOLLICLE BIOLECTROMAGNETISM DELAYING CRYSTALLIZATION
As stated in the present manuscript human blood BEMFs are postulated to cause a delay in the transit time of K3Fe crystallyzation. Is important to mention that the human follicle BEMFs had been previosly shown to delay K3Fe crystallization advance [10]. This is the first time that BEMFs penetrating a 1 mm glass barrier is seen disturbing a hair follicle inherent BEMFs.

DEMONSTRATION OF THE EFFECT OF HUMAN BLOOD BEMFS ON HAIR FOLLICLE METABOLISM
The intrinsic biomagnetism of organs such as the brain and heart have been found to emit bioelectrical signals that could presently be displayed by instrumentation. This manuscript is introducing documentation of human connective tissue (blood) transferring its BEMFs energy onto a human miniorgan (hair follicle). The follicles tested were freshly plucked via tweezers. It has been established that "Although the plucked hair shaft is clearly inferior in cellular quantity and complexity to an intact hair follicle as obtained by a biopsy, it does carry sufficient cellular mass to permit detailed scientific investigations" [11].

SUMMARY AND CONCLUSSIONS
Scientists have found that anisotropic crystals such as Potassium Ferricyanide (K3Fe) fully absorb incoming electromagnetic radiation. Experiments herein presented confirm a human miniorgan tissue (hair follicle) when surrounded by K3Fe fully absorbs the electromagnetic radiation externally emitted by a connective tissue (blood) through a 1 mm glass barrier. This inter tissue energy transfer could aid in the understanding genesis of diseases. For example, could human blood pooling in body cavity transfer energy to surrounding tissue and triggering calcification? What are the physiological implications of the newly introduced dual blood tissue energy transfer mechanism in organs?
Further research is warranted.

SOURCES OF FUNDING
This research received no specific grant from any funding agency in the public, commercial, or not-for-profit sectors.