Biopolym. Cell. 1999; 15(2):138-142.
Structure and Function of Biopolymers
The influence of microwaves of very low intensity on antiport of ions through erythrocyte membranes
1Yemets B. G.
  1. Kharkiv National University
    4, Svobody Ave., Kharkiv, Ukraine, 61077

Abstract

The energy harrier for passive transporting of ions through an erythrocyte membrane is towered as a result of effects of the very low intensity microwaves. This occurs due to decreasing the thickness of a boundary unmixed liquid layer which can be passed through by the ions only by diffusion. The thickness decreasing is caused by intercellular liquid being actively intermixed; this activization is provided by decelerating motions of air bulbs present in the liquid in a temperature gradient field. The temperature gradient caused by the very low intensity microwaves is sufficient for such effects on the water layer situated close to the membrane.

References

[1] Devyatkov ND, Golant B Betsky OV Millimeter waves and their role in life processes. M.: Radio and communication, 1991. 168.
[2] Macey RI, Adorante JS, Orme FW. Erythrocyte membrane potentials determined by hydrogen ion distribution. Biochim Biophys Acta. 1978;512(2):284-95.
[3] Putvinskii AV, Popov SA, Puchkova TV, Danilov IuA, Vladimirov IuA. Electrical breakdown of erythrocyte membranes attributed to the diffusion potential difference. Biofizika. 1983;28(3):505-6.
[4] Chamberlain JE, Chantry GW, Gebbie HA, Stone NVB, Taylor TB, Wyllie G. Submillimetre absorption and dispersion of liquid water. Nature. 1966. 210(5038):790—791.
[5] Regirer SA Lectures on the biological mechanics. M.: Moscow State University Press, 1980. Part 1. 144.
[6] Gavrilov L.R. Free gas content in liquids and acoustic methods of its measurements. Review. Akusticheskij Zhurnal, 1969, 15(3):321-334
[7] Bunkin N. F., Vinogradova O. I., Kuklin A. I., Lobeev A. V., Movchan T. G., Presence of submicroscopic air bubbles in water. Small-angle neutron scattering experiment. JETP Letters. 1995. 62, N 8:659—662.
[8] Kuznetsov, M., Lugovtsov BA, Sher EI The motion of the gas bubbles in the liquid under the influence of a temperature gradient. Zh. prikl. mathematic and tehn. physics. 1966. N 1:124-126.
[9] Yemets B. G. Efficient extraction of gas from the liquid by means of microwaves at a substantially constant temperature. Technical Physics Letters, 1996 22(8):22-24.
[10] Kotyk A., Janacek K. membrane transport. New York: Wiley, 1980. 341.