Influence of normobaric hypoxia on the dynamics of biochemical indicators during the performance of mind work

The aim was to study the effect of normobaric hypoxia on biochemical parameters to assess homeostatic changes caused by mental work.

Materials and methods: 90 highly qualified athletes of various specializations took part in the scientific observation. Athletes performed psychophysiological tests to determine mental performance under normal conditions and under the influence of normobaric hypoxia.

Results: the concentrations of lactate (La), glucose (Glu), cholesterol (Chol), and triglycerides (Trigl) in the blood were measured four times at different stages.

Conclusions: it was shown that athletes after staying in NH conditions significantly increased the La, Glu, Chol and Trigl indices, which indicates the mobilization of energy resources and an increase in anaerobic processes in response to NH exposure. Re-performance of mental work after exposure to NH was associated with a marked decrease in the concentration of Glu, Chol, and Trigl, along with a slight increase in the concentration of La after normobaric hypoxic exposure, there are significant changes in the bioenergetic profile in athletes.

1. Astashova A.N., Fedorov V.P. Mountain training in aviation, medicine, sports. OlymPlus. Gumanitarnaya versiya = OlymPlus. Humanitarian version. 2019;(1):96–101 (In Russ.).

2. Breslav I.S., Volkov N.I., Tambovtseva R.V. Breathing and muscle activity of a person in sports. Moscow: Sovetskii sport Publ.; 2013 (In Russ.).

3. Burykh E.A. General patterns and individual characteristics of the integrative response of the human body to the impact of acute normobaric hypoxia: abstract of thesis Doctors of Medical Sciences. St. Petersburg: Sechenov institute of evolutionary physiology and biochemistry Russian academy of sciences; 2020 (In Russ.).

4. Iordanskaya F.A. Hypoxia in training athletes and factors that increase its effectiveness: monograph. Moscow: Sovetskii sport Publ.; 2015 (In Russ.).

5. Kolchinskaya A.Z. Interval hypoxic training in elite sports. Sportivnaya meditsina = Sports medicine. 2008;(1):9–25 (In Russ.).

6. Kolchinskaya A.Z. Oxygen, physical condition, working capacity. Kiev: Naukova dumka Publ.; 1991 (In Russ.).

7. Balioz N.V., Krivoshchekov S.G. Individual-typological characteristics of the EEG of athletes during acute hypoxic exposure. Human Physiology. 2012;38(5):470–477. https://doi.org/10.1134/s0362119712050027

8. Kapilevich L.V., Ezhova G.S., Zakharova A.N., Kabachkova A.V., Krivoshchekov S.G. Bioelectrical activity of the brain and cerebral hemodynamics in athletes with a combination of cognitive and physical load. Human Physiology. 2019;45(2):164–173. https://doi.org/10.1134/s0362119719010080

9. Ushakov I.B., Fedorov V.P. Oxygen. Radiation. Brain. Structural — functional pattern. Voronezh: Nauchnaya kniga Publ.; 2011 (In Russ.).

10. Blacker K.J., Seech T.R., Funke M.E., Kinney M.J. Deficits in visual processing during hypoxia as evidenced by visual mismatch negativity. Aerosp. Med. Hum. Perform. 2021;92(5):326–332. https://doi.org/10.3357/AMHP.5735.2021

11. Jung М., Zou L., Yu J.J., Ryu S., Kong Z., Yang L., et al. Does exercise have a protective effect on cognitive function under hypoxia? A systematic review with meta-analysis. J. sport health sci. 2020;9:562–577. https://doi.org/10.1016/j.jshs.2020.04.00412.

12. Koryagina Yu.V., Nopin S.V. Hardware-software complexes for the study of the psychophysiological characteristics in athletes. Voprosy funktsional’noi podgotovki v sporte vysshikh dostizhenii [Issues of functional training in elite sports]. 2013;1(1):70–78 (In Russ.).

13. Williams T.B., Corbett J., McMorris T., Young J.S., Dicks M., Ando S., et al. Cognitive performance is associated with cerebral oxygenation and peripheral oxygen saturation, but not plasma catecholamines, during graded normobaric hypoxia. Exp. physiol. 2019;104(9):1384–1397. https://doi.org/10.1113/EP08764714.

14. Samoilov M.O. Reactions of brain neurons to hypoxia. Leningrad: Nauka Publ.; 1985 (In Russ.).

15. Tsyganova T.N. The use of normobaric interval hypo-hyperoxic training in the prevention of mitochondrial dysfunctions (review article). Vestnik novykh meditsinskikh tekhnologii = Journal of new medical technologies. 2019;(2):126–130 (In Russ.).

16. Solkin A.A., Belyavsky N.N., Kuznetsov V.I. The main mechanisms of the formation of brain protection during adaptation to hypoxia. Vestnik Vitebskogo gosudarstvennogo meditsinskogo universiteta = Vestnik of Vitebsk State Medical University. 2012;11(1):6–14 (In Russ.).