A Kink-Soliton Model of Charge Transport Through Microtubular Cytoskeleton

Abstract

Abstract. Contemporary trends in science and technology are characterized by integration of biological and technical systems, like in nanotechnology, nanobiology, and quantum medicine. In our case, we were motivated by a necessity to understand charge transport through microtubular cytoskeleton as a constitutive part of acupuncture system. The high frequency component of acupuncture currents, widely exploited in microwave resonance stimulation of acupuncture system in the past decade, implies that explanation of the cytoplasmatic conductivity should be sought in the framework of Frohlich theory. Accordingly, in this paper we critically analyze the problem of the microwave coherent longitudinal electrical oscillations as a theoretical basis for understanding soliton phenomena in microtubules, showing that charged kink-soliton nonlinear microtubular excitations might be a good candidate for charge transport in microtubules. Introduction Ionic acupuncture currents, and accompanying electromagnetic fields, have both ultralow frequency (ULF) [1] and microwave (MW) [2] components, i.e. the MW component is modulated by the ULF one, this being in overall agreement with the frequency and power windowing in tissue interactions with weak electromagnetic fields The Ukrainian-Russian research and clinical practice in quantum-like microwave resonance therapy (MRT) at ~ 50-80 GHz, fundamentally quantum-informationally efficient even in very serious psychosomatic diseases In this paper the problem of microwave coherent longitudinal electrical oscillations is considered as a theoretical basis for understanding the charged kink-soliton phenomena in microtubules, implying simultaneously the very nature of nondisipative MW electrical signals alongside microtubular cytoskeleton of acupuncture channels in MRT therapy