Radiofrequency emission from water solutions prepared using gradual technology is modulated by a magnetic field
G.O. Stepanov1, N.N. Rodionova1, A.O. Petrova1, V.V. Novikov2, E.V. Yablokova2, D.Yu. Chernikov3, A.V. Minakov3, E.M. Dobychina4, M.V. Snastin4
1 OOO “NPF “MATERIA MEDICA HOLDING”
2 Institute of Cell Biophysics of the Russian Academy of Sciences
3 Siberian Federal University
4 Moscow Aviation Institute (National Research University)
Abstract
Our research is focused on aqueous solutions obtained using gradual technology, i.e., by performing sequential dilutions of the initial substance accompanied by vibrational processing. They are called gradual dilutions (GD). Previously, we demonstrated that GDs differ significantly from controls in their effects on redox reactions (in models with long-lived ABTS and TEMPO radicals), their ability to emit radio waves in different spectral ranges (1290 MHz to 2700 MHz and 4 GHz to 30 GHz), and their dielectric permittivity at frequencies of 100 kHz and 51.2 MHz. Obviously, the ability to emit in the GHz range may be related to the non-contact (distant) activity of these samples. However, it remained unclear whether the radio emission of GDs and their distant properties can be controlled by external physical influences (such as magnetic fields). To clarify this issue, we conducted a comparative study of 1. the ability of GD antibodies (Ab) to IFNg to emit GHz radiation depending on the magnetic field and distance to the GHz detector, and 2. the ability of GD Ab to IFNg to distantly influence a neutrophil suspension. It was shown that the distant effect of GD Ab to IFNg on a neutrophil suspension is manifested in a combined magnetic field and decreases dramatically at 0 magnetic field. It also decreases quadratically with distance. GHz radiation is manifested differently in a combined magnetic field and at 0 magnetic field. Apparently, the mechanisms of the distant action of GDs are mediated by a number of interrelated physicochemical factors that are differently modulated by magnetic field but depend quadratically on distance, i.e., they are likely electromagnetic in nature. A detailed study of energy migration pathways and the subsequent changes in the physical, chemical, and biophysical properties of GDs leads to a deeper theoretical understanding of the processes occurring within them. Various models describing the experimental behavior of GDs (formation of molecular complexes, mechanochemical activation, realization of low-stability states) are currently being actively developed in theoretical and experimental physics . Up-to-date studies explain the mechanisms of radio emission from GD samples through oscillations of ion-stabilized nanobubbles.
Speaker
Stepanov German O.
OOO “NPF “MATERIA MEDICA HOLDING”
Russia
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