Symphony in the Brain

" Since the value of action potential propagating along membrane is well known, typically being close to 70 mV, it is not difficult to calculate the frequency and wavelength of the coherent Josephson radiation coming from contacts of microtubules using equations (3) and (4), respectively [20]. They appear to be about 33.8 THz and 8.8 µm. The chains of connected superconducting microtubules act as ideal transducers of voltage to the frequency of coherent radiation. Each set of microtubules, which are close to the membrane, generates the same radiation. Each neuron generates similar radiation with slight differences defined by the small differences in the action potential. Altogether hundreds of billions of neurons create a symphony like a music in a symphony orchestra. However, in contrast to the orchestra, these are not mechanical vibrations on the kHz frequencies, but electromagnetic waves on the frequencies 10 orders of magnitude higher. There are about 300 strings of the instruments in a typical symphony orchestra, while the number of "strings" in the brain, wich produce coherhent radiation could be as big as 10000000000000. This radiation has very specific spectrum for every alive organism but still in the same range of frequencies close to 34 THz. It is streamed inside and outside of the bodies. Inside, it synchronises functions of organism, outside it is used for communication." {Credits 1}

" The room-temperature superconductivity seems to be very common in biological systems, and the coherent Josephson radiation might be the basis of memory, perception, emotions, in short, nearly everything that we are as the living organisms." {Credits 1}

{Credits 1} 🎪 Mikheenko, P. (2024). Symphony in the Brain. Japan J Med Sci, 2(1), 01-07. © 2024 The Authors. This article is licensed under a Creative Commons Attribution International 4.0 License.