Some principles of the Biophilia Tracker

Some principles of the Biophilia Tracker

The adoption of an oriental reflexology approach led researchers and practitioners to consider the possibility of using electrical current and electromagnetic radiation instead of metal needles or absinthe cigars as influencing factors. In any case, some questions have arisen about the possible and necessary variables of these influencing factors. On this basis, a complete field of electropuncture diagnostics has been formed using different methods (Foll, Nakatany, Nechushkin), which are based on the measurement of skin conductivity in biologically active sites (BAPs). There are currently no experimental data on actual and effective BAP substrates. The most objective evidence of BAP morphology is P.P. Garyaev's view of the intercellular network as a specific signaling system in the human body, including BAP. Intercellular networks, or intercellular substances, can act as specialized supramolecular analogs of neuronal networks, ensuring the directed introduction of information into certain cellular and tissue complexes, including the "Acupuncture Competency Matrix."

Unlike Foll's electrospin diagnostic method, in which the energy potential of organs and tissues is measured through biologically active points (BAPs) that indirectly (often with serious errors) reflect the state of the organ, in nonlinear diagnostics ( The NLS) method, developed by the Institute for Practical Psychophysics (IPP), directly assesses the state of an organ due to the resonant amplification of radiation from the organ under study and the acquisition of readings by a non-contact means involving triggering sensors.

In order to realize the indicated possibilities, we formulated medical technical requirements and technical tasks to develop a new generation of diagnostic devices based on low-frequency quantum generators and developed the Metatron device.

The Biophilia Tracker device is designed to unequivocally assess the physical condition through reordering changes in organ and histological structures, to dynamically control the state of homeostasis, and to predict the stage of treatment and complication development. The diagnostic device allows physicians to significantly reduce the time to definitive assessment of the physical condition of the system as a whole. Designed to record changes in organ and histological structure, the device is able to:

- qualitative assessment of the functional state of the body based on local analysis;

- checking the effectiveness and results of the treatments used;

- assess the body's ability to adapt;

- Analyze the dynamic changes of the body's functional state during treatment;

- reveal the main nature of the dysfunctional lesions;

- use of expert systems to define pathological features;

- Assess the main variables of steady state.

The device is designed to be used only in conjunction with a computer complex based on an IBM compatible computer and software developed by the parent company. The device works according to the principle of amplification of the start-up signal and the decomposition of the metastable structure.

The magnetic moments of molecular currents in the mixing centers of cortical nerve cells affected by external electromagnetic fields lose their original orientations, causing the spin structure of the delocalized electrons to misalign, leading to their unstable metastable conditions, whose decomposition acts as an initiation signal.

In terms of physics, the device is a system of electronic oscillators that resonates at wavelengths of electromagnetic radiation with enough energy to break the primary bonds that maintain an object's structural organization.

The device was able to generate the prescribed bioelectrical activity of the neurons in the patient's brain, for which they gained the ability to selectively amplify signals that barely detect static fluctuations (the phenomenon of resonance).

Information on specific temporary organ conditions is collected in a non-contact manner through trigger sensors developed with the help of new information technologies and microcircuits. The sensor detects weak detectable signal fluctuations picked from the average statistical noise field signature and converts it into a digital sequence that is processed by a microprocessor and transmitted to a computer via an interface cable.

Ensure device operation mode, adjustment and control according to installed program. Information about the results of a particular patient's diagnostic procedure is displayed on a monitor screen and is stored in a separate file on the computer's hard drive and can be transferred to a separate floppy disk.