Article Type: Research Article Article Citation: Abrahám A. Embí BS (2020). EVIDENCE OF
TELEPORTED BIOELECTROMAGNETIC ENERGY TRANSFER IN A HUMAN MINIORGAN CAUSING
DELAY IN CRYSTALLIZATION. International Journal of Research -GRANTHAALAYAH, 8(6),
156-162. https://doi.org/10.29121/granthaalayah.v8.i6.2020.484 Received Date: 09 May 2020 Accepted Date: 29 June 2020 Keywords: Hair Bioelectromagmetism Inter Body Energy Transfer Hair Shaft Potassium Ferricyanide Delay in Crystallization The purpose of this manuscript is to introduce an optical microscopy methodology documenting an organ inter-tissue parts bioelectromagnetic energy transfer, namely the human hair follicle transferring energy to a short-isolated cut hair shaft segment vertically placed within ≅ 1 mm distance in front of the hair follicle. The human hair has two main parts, follicle and shaft and classified as a miniorgan having its own cell divisions and metabolism. Both the follicle and shaft has been independently documented to emit and receive electromagnetic energy. This work shows a previously unrecognized property of the hair shaft, which is acting as an aerial receiver and conduit of Bioelectromagnetic Fields (BEMFs) emitted by the follicle. The received BEMF energy is transient and transferred via teleportation to be immediately discharged by the cut isolated shaft segment. The discharged crystallization imprint mimics the hair follicle proper BEMFs delaying advance of crystallization.
1. INTRODUCTIONThe main purpose of this manuscript is to expand on previous
observations of different human tissue or body parts induction of
electrobiomagnetic energy [1].
Research has led to classifying the hair follicle as a dynamic miniorgan,
having its own “important general molecular and cellular
processes beyond skin and hair biology, ranging from organ induction,
morphogenesis and regeneration, to pigment and stem cell biology, cell
proliferation, migration and apoptosis” [2]. This manuscript introduces
biophysical properties of the human hair by documenting an inter-transfer of
bioelectromagnetic fields (BEMFs) between the follicle and its shaft. For the purpose of this presentation the term
“Bioelectrobiomagnetic” will be used Why? Because since biomagnetism is defined
as the “The existence of weak fluctuating
magnetic fields produced by the human body” [3] and
these magnetic fields can induce electrical signals are in support of a more
specific term, such as Bioelectrobiomagnetic Fields (BEMFs) [4]. In Vitro experiments will show BEMFs
emitted by a hair follicle transferring onto a hair shaft as evidence of
Bioelectromagnetic reception and transmission by the shaft evidenced by a delay
in crystallization. 2.
MATERIALS AND METHODS
2.1. MATERIALS
Potassium FerrIcyanide Crystal. K3Fe(CN)6. CSA # 13746-66-2. · Microscope - Glass Slides: 25x75x1mm thickness. Pearl Cat. No. 7101 · Water purity confirmed by hand held electrical fields detector manufactured by Lishtot Detection LTD, Israel. For details link to: https://www.lishtot.com/TDP1.html · Room relative humidity monitored by an ACU-RITE sensor model # 01536-RX. · Digital Video Microscope Celestron II model # 44341, California, USA. · Images downloaded to an Apple Computer MacBook Pro Photo Application. 2.2. METHODSThe Single Slide Preparation (SSP) A single slide preparation (SSP) [5], [6] consists of a single 25x75x1mm clean glass slide, where the biological sample is covered with drops of diluted crystals, in this case Potassium Ferricyanide crystals (KFe3). All hair samples were placed approximately on the center of a 25x75x1mm glass slide. A solution was prepared by using 1 ml of bottled water whose purity was confirmed via a handheld electrical field detector (see materials), then delivered into a test tube where one gram of KFe3 crystals were already placed and manually shaken until the crystals were in solution, a small pipette placed inside. Two drops of the mixed KFe3 (paramagnetic solution) were delivered; care was taken to completely cover tweezers pluck scalp hair and isolated cut shaft segment. Using a wooden toothpick, previously cut short shaft segment was then vertically positioned at approximately 1 mm distance from the hair follicle. The SSP preparation was then allowed to evaporate. After a complete and total evaporation lasting approximately 45 minutes, the SSP was then viewed microscopically in the normal mode (no filters) at X10 and/or 40X magnification with a video microscope (Celestron. LCD Digital Microscope II model #44341 Torrance California USA). Still microphotographs and video recordings were downloaded and labeled by using an Apple Inc. iPhoto 8.1.2, App. 3. RESULTS3.1. BIOELECTROMAGNETISM AND CRYSTALLIZATIONSeveral observations were demonstrated by the in vitro experiments, such as: Inhibiton of
Bioelectromagnetic Waves are we witnessing BEMFs teleportation? · Since the hair follicle and isolated shaft are imbedded in a liquid solution undergoing evaporation, this author expected to see crystallization patterns compatible with BEMFs. This did not occur (See Figure 1). The inhibition of concentric bioelectromagnetic waves emitted by the hair follicle commonly observed in a SSP which are outlined by dense KFe3 crystallization. This inhibition is highlighted by X as shown in (Fig 1). Refer to Figure 3 below for comparison. Since the BEMFs did not induce crystallization between the follicle and the isolated shaft segment, then the question arises: Are we demonstrating BEMFs teleportation?
Figure 1: Microphotograph of video frame showing a short cut hair shaft segment placed in front of hair follicle inhibiting crystallization in aSSP KFe3 after evaporation. X: Denotes absence of periodical biomagnetic trails. Clashing of
Diamagnetic with Paramagnetic Fields Delay Crystallization · In a control SSP, the observed compactness of the KFe3 is attributed to the clashing of divergent magnetic waves, a repelling incoming magnetism or diamagnetism from the hair follicle, with the paramagnetism of (attraction towards a magnetic field) KFe3 producing a noticeable back (diamagnetic repulsion) and forth (paramagnetic advance) clashing of forces, please refer to Panel 1 + video-recordings below.
Panel 1: Blue arrow showing BEMFs flow direction of hair follicle. A: Control hair in SSP KFe3 showing orderly semicircular crystallization from biomagnetic waves. B: Showing a cut hair shaft segment placed in front of the follicle. The follicle is now via teleportation transferring its biomagnetism onto the shaft issue serving as a conduit. Blue Arrow, panel A showing unimpeded biomagnetic waves progression. Blue Arrows Panel B, biomagnetic waves now flowing through (cut hair shaft) or alternative conduit. For additional details Scan QR Codes attached to images. Panel A evaporation time 3’ 29” Panel B evaporation time 4’00 The Isolated Hair
Shaft Lacks Intrinsic BEMFs · When a hair shaft is not under the influence BEMFs, the KFe3 crystals are less compacted, this is attributed to a lack of BEMFs clashing between a diamagnetic and a paramagnetic solution (KFe3) as shown in Figure 2 below. This is evidence that the hair shaft by itself lacks the level of metabolic activity necessary to emit BEMFs. Demonstration of
Rapid Crystallization Advance from an Isolated Cut Shaft Segment
Figure 2: Independent cut hair shaft segment not influenced by divergent bioelectromagentic forces attracting KFe3 crystals. Black Arrow: Pointing at less compacted KFe3 crystals. For details link to: https://youtu.be/Yolgu-vFeK0 Or scan QR Code in left upper corner of image. Evaporation time 1’ 40”. Clashing of Hair
BEMFs Through Glass Barrier Delays Crystallization · When a Ferricyanide or Ferrocyanide solution is within BEMFs reach, the ensuing crystallization is not only delayed; but shows a greater crystals clumping Fig 3 below. The hair follicle BEMFs delay the Ferro or Ferri cyanide crystallization progression for an average of approximately 4 minutes. (Panel 2).
Figure 3: Another example of hair follicle’s BEMFs effect on evaporation dynamics and crystals deposition of Potassium Ferrocyanide. F= Follicle Highlighted Arrow= Heavy crystallization lines. Example of a hair follicle BEMFs delaying the crystallization advance of a KFe2 solution through a 1 mm glass barrier [7].
Panel 2: Notice the rapid advance of the Potassium Ferrocyanide evaporation line during the first 29 seconds. As the evaporation line reaches the hair follice/shaft outline, there is a noticeable delay in progression. This is an example of repulsion caused by the EBMFs effect of a human hair follicle detected by a diamagnetic solution through a 1 mm glass barrier. For details link to:
https://youtu.be/6iKcEvxY_zE Or Scan QR Code below. Panel reproduced from: Cite This Article: Abraham A. Embi Bs. (2018). “THE HUMAN HAIR FOLLICLE PULSATING BIOMAGNETIC FIELD REACH AS MEASURED BY CRYSTALS ACCRETION.” International Journal of Research - Granthaalayah, 6(7), 290-299. https://doi.org/10.5281/zenodo.1341349. 4. DISCUSSION· The human hair has two main anatomical components (the follicle and shaft) and classified as a miniorgan; and herein demonstrated in two different experiments as expressing inter-tissue energy transfer between the follicle and shaft. This transfer did not trigger KFe3 localized crystallization, thus supporting a teleportation phenomenon. · BEMFs are shown to delay crystallization A human miniorgan is shown transferring BEMFs from the hair follicle to an isolated short hair shafts segment vertically placed at 1 mm distance. · The delaying advance of a paramagnetic solution (KFe3). This is quantitatively demonstrated in the time measured of an average of 4 minutes, only when BEMFs are a factor. Both the follicle and shaft display magneto reception properties exhibited by BEMFs induction. This mechanism has been described in birds [5]. · Further support of the crystallization delay had been documented in a separate experiments showing a stark slowing of crystallization, this time Potassium Ferrocyanide in solution mixed with very fine iron particles of 2000 nanometers in diameter or (KFe22K) was used. This phenomenon was documented in Panel 2. In that experiment the BEMFs had penetrated a 1 mm glass barrier [7]. 5. SUMMARY AND CONCLUSSION5.1. THE HUMAN HAIR AS A BIOELECTROSENSORY MINIORGANThe findings herein presented support the hair to be described as a Bioelectrosensory miniorgan. Both the follicle and the shaft are theorized to have electro receptive molecules. When a freshly plucked hair is in a control SSP KFe3 preparation and allowed to evaporate, there are concentric periodic heavy crystallization semicircles (Fig 3). When in the same preparation, the follicle is fronted by a vertically placed isolated short shaft segment, the evidence show the follicular BEMFs bypassing the area between the follicle and the isolated shaft. The BEMFs are discharged by one end of the cut shaft (Panel 1), that these heavy concentric crystallization discharges mimic hair follicles in control experiments. The observed BEMFs bypassing mechanism could point at teleported BEMFs. It was also demonstrated that BEMFs delay the crystallization advance of Ferro (Panel 2) and Ferri (Panel 1) cyanides in solution. 5.2. ADDENDUMSuggested Methodology
to Duplicate the Reported Findings CAUTION Avoid Failure to Centering Isolated
Cut Shaft and Failure to Keep Distance from Follicle To aid the reader in duplicating the experiments, care must
be taken to center the isolated short hair shaft segment vertically away from
the follicle at ≅
1 mm lateral distance.
Failure to centering is shown in Figure 4 below. Avoid Improper Centering of Isolated
Cut Shaft Segment
Figure 4: Cut shaft touching the follicle and non-center aligned. SSP KFe3 after evaporation- Black Arrows: Showing BEMFs energy dissipation bypassing misplaced obstacle (cut shaft); and triggering what appears to be electrical discharges. Please compare to Panel 1 and Figure 1 above. Avoid Having a Non-Vertical
Contiguous Follicle, Long Isolated Shaft Connection. BEMFs appear to dissipate through the shaft (Figure 5). The videorecording demonstrates an absence of heavy periodic crystallization exiting the shat. This observation is documented in the last few frames of videorecording.
Figure 5: Showing disruption of concentric BEMFs waves by isolated cut shaft in contiguous (direct) contact with follicle. X: Area void of concentric crystallization. Black Arrow: Pointing at amplified image of isolated shaft touching follicle. For additional details link to: https://youtu.be/arcpZLkYqP0 Or scan QR Code in left upper corner of image. SOURCES OF FUNDINGNone. CONFLICT OF INTERESTNone. ACKNOWLEDGMENTNone. REFERENCES
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Schneider, M. R.,
Schmidt-Ullrich, R., & Paus, R. (2009). The hair follicle as a dynamic
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[4]
Burnei, G., Hodorogea,
D., Georgescu, I., Gavriliu, Ş., Drăghici, I., Dan, D., Vlad, C.,
& Drăghici, L. (2012). The electromagnetic bio-field: clinical
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