Pathophysiological bases of maladjustment formation in high mountains and polar zones

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Abstract

The pathophysiological features of the development of maladjustment under mountain-cold conditions as a manifestation of the syndrome of mutual burdening are considered. In this study, contents of various literary sources, characterizing a person’s resistance to the effects of a complex of factors under high mountains and polar zones conditions, were analyzed. With the simultaneous exposure to hypoxia and hypothermia from a pathophysiological point of view, intersecting links of terminological “paths,” often having diametrically opposite dynamics of changes in the characterized concepts, will be significant. Thus, in the terminological mitochondrial “pathway” of energy metabolism, uncoupling proteins are present, which, to increase the resistance to hypothermia, should be activated to switch the energy metabolism to predominantly use fatty acids. However, hypoxic conditions should be suppressed to maintain the level of adenosine triphosphate acid available for cells. In the terminological tract of compensatory reactions in response to hypoxemia, the volume of pulmonary ventilation is released, which must increase to improve tolerance to hypoxia, which, under mountain-cold conditions, increased heat loss and promote the deterioration of the condition, i.e., tolerance to low temperatures. Under hypoxic and hypothermic conditions, a synergistic interaction can form, which can be manifested by the development of a syndrome of mutual burdening, which will result in a significant decrease in the functional capabilities of the body, result, and productivity. Maladjustment to mountain cold, with maximum probability, will manifest as disorders of the central nervous system, decreased physical performance, depletion of the functional and regulatory reserves of the body, functional immunodeficiency, decreased regenerative potential, and development of endogenous intoxication. With a high degree of probability, a significant synergistic interaction of hypoxia and hypothermia can be found in relation to the indicators of pulmonary ventilation, blood gases (hypercapnia), acid–base balance (gas alkalosis and lactic acidosis), heart rate (tachycardia), blood pressure (hypotension), central venous pressure (increase), blood viscosity (increase) and its coagulability (hypercoagulation), peroxide and free radical oxidation (activation), and protein catabolism (increase). These changes will negatively affect the functional state of specialists performing complex professional tasks in polar latitudes.

About the authors

Aleksey E. Kim

Military Medical Academy named after CM. Kirov Ministry of Defense of the Russian Federation

Author for correspondence.
Email: alexpann@mail.ru
ORCID iD: 0000-0003-4591-2997
SPIN-code: 7148-1566

candidate of medical sciences

Russian Federation, Saint Petersburg

Evgeniy B. Shustov

Scientific and Clinical Center of Toxicology named after acad. S.N. Golikov FMBA of Russia

Email: shustov-msk@mail.ru
SPIN-code: 9665-6670

doctor of medical sciences, professor

Russian Federation, Saint Petersburg

Aleksey V. Lemeshchenko

Military Medical Academy named after CM. Kirov Ministry of Defense of the Russian Federation

Email: lav_1981@mail.ru
ORCID iD: 0000-0001-6786-2332
SPIN-code: 8534-0822

candidate of medical sciences

Russian Federation, Saint Petersburg

Vasily N. Tsygan

Military Medical Academy named after CM. Kirov Ministry of Defense of the Russian Federation

Email: vn-t@mail.ru
ORCID iD: 0000-0003-1199-0911
SPIN-code: 7215-6206

doctor of medical sciences, professor

Russian Federation, Saint Petersburg

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Copyright (c) 2021 Kim A.E., Shustov E.B., Lemeshchenko A.V., Tsygan V.N.

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