INTRODUCING GAP IN HAIR FOLLICLE ELECTROMAGNETISM AS MECHANISM FOR THE PRESENCE OF BIPOLAR ELECTRICAL CHARGES INHERENT IN THE HUMAN HAIR SHAFT

The human hair consists of a follicle anchored in the skin and a protruding shaft, it has also been described as a miniorgan, having its own cell divisions, metabolism, and known to undergo aging stages; eventually reaching a point where the old hair sheds and a new hair growing cycle begins from the same follicular tissue. Using sophisticated magnetometers, magnetic field emitted by direct current (DC) in human hair follicles were detected and introduced in 1980. Most recently in 2015, a tabletop optical microscopy method was developed and published in 2016, thus allowing for the detection of hair follicles and shaft magnetic fields. Qualitative images are presented where the bipolar electrical property of the shaft is documented. This finding was inferred since blood tissue carries a negative charge, thus repelled by an equal charge; experiments support a positive (+) field as triggering coagulation. The shaft is repeatedly shown in experiments to express a contralateral positive side triggering. Fibrin formation is also documented by images showing intricate networks indicative of blood coagulation. In conclusion, the genesis of hair shafts bipolarity is shown resulting from a “gap” in the follicle electromagnetic fields inhibiting energy from fully engulfing the shaft.


INTRODUCTION
The human hair consists of a follicle anchored in the skin and a protruding shaft, it has also been described as a miniorgan, having its own cell divisions, metabolism, and known to undergo aging stages (Schneider et al. (2009)); eventually reaching a point where the old hair sheds and a new hair growing cycle begins from the same follicular tissue. Using sophisticated magnetometers, magnetic field emitted by direct current (DC) in human hair follicles were detected and introduced in 1980 ( Cohen et al. (1980)). Most recently in 2015, a tabletop optical microscopy method was developed and published in 2016, thus allowing for the detection of hair follicles and shaft magnetic fields (Scherlag et al. (2016)). When a hair shaft is in contact with fresh blood tissue on a slide, an interesting finding occurs, which is one side inducing blood coagulation and the opposite side inhibiting of coagulation.

METHODS
1) A fresh human blood smear obtained. Solution prepared by diluting approximately 2 milligrams of (K 3 Fe) diluted in one drop of demineralized water was added to the center of a wet smear*. Note: 1 * A finger stick allowed for the milking of two drops of blood, then placed on a clean 25x75x1 mm glass slide. The mechanical smear was done as per published instructions from the USA center for disease control. There is a time window of approximately 60±20 seconds for a complete for preservation of in vivo properties of the blood tissue. For details link to: (https://doi.org/10.5281/zenodo.3472760) 2) One freshly tweezers plucked scalp hair was carefully placed in approximately the area where the of the liquid K 3 Fe displaced the blood tissue.
3) The preparation allowed evaporating, Images recorded and stored for analysis.

RESULTS AND DISCUSSIONS
Prior research by this author showed the follicle and shaft magnetic fields properties on a glass slide (in the absence of blood) with the addition of only liquid K 3 Fe, as shown in images showing the hair shaft unilateral presence of electromagnetic radiation (EMR) (Embi (2018)) ( Figure 1). In this manuscript, qualitative images are presented where not only the bipolar electrical property of the shaft is documented; but also showing EMR originating from the hair follicle routed only to one side of the shaft, a gap in the hair follicle's EMR continuity accounting for the shaft's bipolarity (+ −) ( Figure 2, Figure 3).

Potassium as Immunosuppressing Agent
The rejection of several exogenous materials, such as a hair follicle, keratin flakes and small iron filings amongst others by a fresh human blood smear had been described, Figure 7  ).
In this manuscript, the addition of liquid K 3 Fe to a fresh human blood smear inhibited rejection of an in toto hair (follicle and shaft). This inhibition allowed for images such as in (Figure 2, Figure 3, Figure 4, Figure 5). The question arises: What is the mechanism whereby addition of liquid K 3 Fe to a fresh blood smear inhibits fresh blood from rejecting a hair follicle?
Perhaps some elucidation could be explained by findings where a link between tumor-induced immune suppression by the Potassium ion (K + ) exists (Vodnala et al. (2019)).

K 3 Fe Total Absorption of Incoming EMRs Hair Shaft Polarity and Blood Coagulation
Liquid K 3 Fe allowed for the display of hair follicle and shaft EMR as shown (Figure 2, Figure 4). A second important observation is the findings or previous papers correlating a positive charge with blood coagulation. Early in 2018, an image was recorded showing what appeared to be a one-sided electrical discharge in a human hair shaft. (Figure 1). There was not enough published experimental data found by this author to support a hair shaft bipolarity finding.
The question arose: How could a keratin surrounded filamentous structure express opposite sides charges?

Prior Publication Hinting at Bipolarity Potassium Ferrocyanide Spatially Detachment of Shaft Exo-Cuticles
A paper published in 2016, showed that when a human hair shaft was sandwiched between two glass slides and covered by Potassium Ferrocyanide (Embi (2016)), post evaporation, microscopy images showed an unexplained phenomenon, being the spatially separated images of hair exocuticles. In other words, there was a need of a microscope depth of field adjustment to bring the cuticles layers in focus as shown in Figure 6 below.
Evidence shows that the addition of one drop of liquid K 3 Fe onto a fresh blood smear inhibited rejection of a foreing material, namely a plucked human hair. This inhibition, allowed for the identification of the hair EMRs. This is supported by a property of K 3 Fe being the "Full absorption od incoming EMRs" ( Figgis et al. (1969), Baranov et al. (2015)) The hair unique electromagnetic radiation pattern is shown partially engulfing the follicle. There is a "gap" shown in the images that does not allow the magnetic signal from traveling to one side of the hair shaft. The Hair Shaft Inherent Unilateral Divergent Charges (+ −) are displayed.

The Dual Consequences of Follicle's EMR Gap
First) The abrupt interruption of EMRs in one side of the hair follicle, accounts for the hair shaft's one-sided EMR activity triggering positive charges.
Second) The genesis of a visual display resembling a "Shepherd Hook" pattern of the human hair EMR emissions.

SUPPLEMENTAL INFORMATION
Upon re-visiting my files, found some video-recordings where the hair was physically removed from the glass smear-Since the hair had been covered by Potassium Ferricyanide i(K 3 Fe) in solution; and K 3 Fe has the property of full absorption of incoming electromagnetic radiation (EMR), the hair outer layers EMR are shown as K 3 Fe crystals. These images are introduced for the first time in this manuscript-Notice the consistent narrowing between the distal follicle and the bulb- Figure 9 Showing sequential images from video-recordings outlining the human hair external electromagnetic radiation. Black Arrows: Notice the narrowing shown between the distal follicle and the bulb also showing a gap in energy continuity. This gap is theorized to induce the bipolar nature of the shaft (+-). TIBS= Temporary In Vivo Blood Smear. Orange Arrows: Pointing at area where shaft exits towards skin.

Figure 10
Cut and Paste frames to illustrate the human scalp hair magnetic imprint post hair removal from slide. Scalp hair in fresh blood smear mixed with liquid Potassium Ferricyanide. After drying, outer layers of hair are delineated showing hair anatomical areas. Human hair magnetic Imprint on glass slide. Drawing on right side of figure reproduced as described in the copyright fair use doctrine.