BIOIMPEDANCE MODELS AT THE NONLINEAR VOLT-AMPERЕ CHARACTERISTIC AND REVERSIBLE BREAKDOWN OF THE DIELECTRIC COMPONENT OF THE BIOMATERIAL

Research objective: improvement of screening systems of diagnostics of socially significant diseases by modeling of volt-ampere characteristics of bioactive points (BAP) and classification of received models by means of computer technologies.

Research problems:

– development of structurally functional model of electric conductivity of a biomaterial in abnormal zones (in the field of acupuncture points);

– development of a method of formation of space of the informative signs intended for qualifiers of a functional condition of a biomaterial.

Material and methods. For the solution of objectives methods of the theory of linear electric chains, methods of mathematical modeling were used. When modeling conductivity of a biomaterial as tools Matlab 8.0 was used.

For modeling of the volt-ampere characteristic of BAP it is offered to use structural-functional models with diode-resistive cells of symmetric structure. The method of formation of space of the informative signs intended for qualifiers of a functional condition of a biomaterial, the volt-ampere of characteristics of a biomaterial consisting in registration in each bioactive point by impact on them by the constant tension stabilized on level in the range from –15 V to +15 V, changed with a step in 1 V is developed. By comparison of characteristic points of the volt-ampere characteristic and parameters of structural-functional model the vector of informative signs intended for the neuronetwork qualifier is formed.

Results. The structural-functional model of conductivity of a biomaterial on the basis of diode-resistive cells is constructed. The factorial analysis of volt-ampere characteristics of biomaterials on the basis of which it is shown is carried out that for creation of structural-functional model of conductivity of a biomaterial there are enough seven diode-resistive cells.

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