TITLE:
Mechanical Microvibrations as a Basis Organization of Functional Cells Groups
AUTHORS:
Gennady A. Shabanov, Elena A. Lugovaya, Sergey P. Kryzhanovsky
KEYWORDS:
Cellular Functional Group, Mechanical Microvibrations
JOURNAL NAME:
Journal of Behavioral and Brain Science,
Vol.15 No.3,
March
31,
2025
ABSTRACT: The paper proposes a conceptual model in which for each function—from cellular to organism, a frequency cluster (group) consisting of nerve, glial or any other cells is built based on needs. The organizing factor of these cells is one frequency of mechanical microvibrations, and the functional state of such groups is determined by their total amplitude. To record the spectrum of acoustic signals from the head, a prototype of the medical device “Recorder of the spectrum of the brain acoustic field RS AEG-01” was developed. The device, using piezoceramic vibration sensors, recorded the total rhythmic activity separately for the right and left hemispheres and performed its high-resolution spectral analysis in the frequency range from 0.13 to 27 Hz. The 8400 central frequencies obtained from the left and right hemispheres with the corresponding spectral evaluation amplitudes were folded into two spectral matrices measuring 24 × 175 frequency cells. The signal summation time for each spectral cell was chosen to be 160 sec—the duration of the information frame. The paper presents examples of recording and analyzing cell groups of the skin, taste, visceral, and cognitive analyzers. In conclusion, the main principles of constructing a model for organizing a cell functional group are highlighted—mechanical vibrations at low frequencies propagate in the body’s environments with virtually no attenuation; gene expression and synthesis of protein components are sources of mechanical microvibrations. Cells respond to mechanical microvibrations selectively only at their own frequency.