COMPATIBILITY OF BIOMAGNETIC PROFILES FOUND IN LIVING MATTER BY CROSS SPECIES DEMONSTRATION

Biomagnetic research is the study of living entities (plants or animals) weak magnetic emissions. The purpose of this manuscript is to present a historical review and evolution of techniques introduced with the purpose of demonstrating bioelectromagnetic emissions of living tissue; as well as its potential uses in medical research. This will be accomplished by revisiting prior research papers. The hair follicle has been described as a miniorgan, having cellular divisions, thus metabolism. As previously described “metabolism entails electron transfers in both plants (photosynthesis and respiration) and animals (cellular respiration) involving movement of electrons from donor to acceptor along the electron transfer chain thus inducing a current within each cell and from cell to cell. According to Faraday’s Law and the Hall Effect, these currents induce electromagnetic fields (EMFs) perpendicular and horizontal, respectively, to the plane of the living tissues”. Originally the recordings entailed use of complex magnetic shielding and instrumentation. Recently, two tabletops microscopy techniques were introduced, the first using a Prussian Blue Technique mixed with fine iron particles (2000 nanometers in diameter), the second utilizes a three-tier methodology, where cross species magnetic profiles compatibilities are recorded. The utility and medical applications of the two tabletop techniques are discussed


Brief History of Human Biomagnetic Research The Magnetic Shielding Era
The field of Biomagnetism is the study of living entities low-level (weak) magnetic emissions. The challenge encountered by early researchers was how to shield the very weak magnetic fields emitted by the human body from outside interference. This was accomplished by utilizing heavy magnetic shielding and a magnetic gradiometer. Http://www.granthaalayah.com ©International Journal of Research -GRANTHAALAYAH [85] Records show that in the early 1960' the first report of Electromagnetic Fields (EMFs) measurements were done from the human body (1). Progress continued by recording EMFs from the brain, heart and hair follicles (2,3,4). This pioneer work utilized magnetic shielding and sophisticated sensors. This manuscript re-introduces a tabletop microscopy technique that enables the user to easily display individual or paired magnetic profiles amongst living entities in an ecosystem.
The Prussian Blue Stain/iron Era A major breakthrough in biomagnetic research occurred in 2015 by the introduction of a tabletop optical microscopy technique that allows for the recording of weak electromagnetic signals from crystals accretion of an evaporated solution containing Prussian Blue Stain (PBS) and fine iron particles (5). The PBS/iron technique relies in the paramagnetic property (attracted to a magnetic field) of iron imbedded in PBS crystals. This approach resulted in numerous publications by this author and others. For example, a paper in particular documented for the first time the inherent property of electromagnetic energy emitted by the hair follicle (6), EMFs penetrating through glass barriers (7), paired (fronted) hair follicles inhibiting diamagnetic crystals formation (8).
Additionally, in the field of cross-species biomagnetism, similarities were documented between mosquitoes and humans hairs (9). Further research also showed insect pollinators (ants) and flowering plants parts (leaves edges, pistils) also attracting ferricyanides crystals as a reflection of biomagnetic attraction. This led to a Pollination-Cross Species Biomagnetic Hypothesis (10). Since biomagnetic fields travel through glass, it was also theorized that it could travel through air; therefore papers were published where in vivo hair follicles electromagnetic images were recorded on the skin surface through glass barriers (11,12). A recent paper seems to validate the prior research herein presented, why? Because for the first time by using the crystals accretion approach, the vertical Biomagnetic Field Reach (maximum distance EMFs traveled) of the human hair follicle was measured to be approximately 3 mm. Also introduced is a new paradigm; namely, The Pulsating Nature of Biomagnetism (13).

The Beginnings of the Magnetic Profiles Era
While observing hair follicles immersed in water drops, on occasions and while the videomicroscope depth of field was being changed, some spatially related concentric and semicircles lines were displayed. The images were sent for review to a renowned physicist and to my surprise, they were interpreted as Lorentz Forces and Cyclotron Resonance patterns (13). This led to the first paper demonstrating magnetic profiles patterns on the mosquito proboscis and human blood. These profiles were hypothesized as factor in under the skin blood source location by the female mosquito (14). Please visit Materials and Methods section for further details. http://www.jnsci.org/content/186

Hair Follices Biomagnetic Profiles
Since the hair follicle has been described as a miniorgan, having cellular divisions and metabolism, it was chosen for the display of magnetic profiles. Utilizing the technique previously described, a series of experiments showed through images and video-recordings of some unique findings displayed

This video recording validates the magnetic profiles technique
Notice the lack of profiles when the mosquito body parts are not influenced by the human blood intrinsic biomagnetism. profiles as the depth of focus was changed. A= Leg B= Proboscis C= Pair of Palps D= Blood SDW boundary. Please refer to supplementary video # 7 https://youtu.be/CMYSB4hNQYY Female mosquito stylet blood seeking mechanism Theorized is that the mosquito mouth part entering the skin relies on its own magnetic profile to detect the biomagnetic signal from circulating blood in a capillary.

Summary and Conclusions
A brief summary of the history of Biomagnetic research was presented. The Magnetic Profiles Technique was presented and validated. Two areas of usefulness of the new magnetic technique are:

Medical Applications of the Technique
Medical applications: This technique could be used as a laboratory tool to aid in the diagnoses of hair loss syndromes, such as Telogen Effluvium (15). Why? Because, for example in Telogen effluvium a reduction in the magnetic profiles would indicate tissue death (16) in the distal follicle (most inner part inside the skin). This phenomenon is clearly shown in the figures below.