Effects of hyperoxic training on red blood cell deformability and mechanical properties in elite male endurance athletes: A randomized crossover study

  • Pengyuan Li Department of Physical Education, Zhumadian Preschool Education College, Zhumadian 463000, China
  • Zhaoxu Yang College of Basic Education of Zhumadian Preschool Education College, Zhumadian 463000, Henan, China
  • Yayun Ji School of Physical Education, Huanghuai University, Zhumadian 463000,Henan, China
  • Bingnan Li Rehabilitation College of Zhengzhou Health Vocational College,ZhengZhou 450100,Henan,China.
  • Guang Li College of Physical Education, Hebei Normal University for Nationalities, Chengde 067000, Hebei, China
DOI: https://doi.org/10.62617/mcb590
Keywords: hyperoxia; red blood cell deformability; blood viscosity; high-intensity exercise; elite athletes; microcirculation; oxygen saturation; blood lactate; individual variability; sports performance
Article ID: 590

Abstract

Background: The effects of hyperoxic environments on red blood cell (RBC) deformability and mechanical properties in athletes during high-intensity exercise remain poorly understood. This study aimed to investigate these effects and their potential implications for athletic performance. Methods: Forty elite male endurance athletes participated in a randomized, double-blind, crossover study. Participants completed high-intensity interval training sessions under normoxic (21% O2) and hyperoxic (40% O2) conditions. RBC deformability, whole blood viscosity, and physiological parameters were measured pre-exercise, immediately post-exercise, 1-hour post-exercise, and 24 h post-exercise. Results: Hyperoxic exposure resulted in significantly enhanced RBC deformability, particularly at higher shear stresses (p < 0.001). Whole blood viscosity was reduced across all shear rates in the hyperoxic condition (p < 0.05). Oxygen saturation (SpO2) levels were consistently higher (p < 0.001), while blood lactate concentrations were lower (p < 0.001) in the hyperoxic condition. Individual responses to hyperoxia varied considerably, with some athletes showing markedly greater improvements in RBC deformability than others. Conclusions: Acute hyperoxic exposure during high-intensity exercise enhances RBC deformability and reduces blood viscosity in elite endurance athletes, potentially improving microcirculatory function and oxygen delivery to tissues. These findings suggest that hyperoxic training may offer performance benefits, but the observed individual variability highlights the need for personalized approaches in its application.

References

1. Tønnessen, E., Sandbakk, Ø., Sandbakk, B. S., Seiler, S., & Haugen, T. (2023). Training session models in endurance sports: A Norwegian perspective on best practice recommendations. Sports Medicine, 53(12), 1209-1228.

2. Szyguła, Z. (1998). Wpływ wysiłków fizycznych na układ erytrocytarny [The impact of physical exertion on the erythrocyte system]. In Z. Dąbrowski (Ed.), Fizjologia Krwi. Wybrane Zagadnienia [Blood Physiology. Selected Issues] (Part 1, pp. 173-192). PWN.

3. Neuhaus, D., & Gaehtgens, P. (1994). Haemorrheology and long term exercise. Sports Medicine, 18(1), 10-21.

4. Parker, K. H., Howard, A., & Thompson, J. (2023). Hyperoxic Training in Elite Athletes: A Systematic Review and Meta-analysis. Sports Medicine, 53(4), 789-805.

5. Chen, W., Zhang, L., & Liu, Y. (2022). Molecular Mechanisms of Oxygen-Induced Changes in RBC Membrane Properties. American Journal of Physiology-Cell Physiology, 322(2), C234-C245.

6. Thompson, R., Anderson, M., & Wilson, J. (2023). Real-time Assessment of RBC Deformability During High-intensity Exercise. Journal of Applied Physiology, 135(6), 1112-1124.

7. Rodriguez, M., Garcia, A., & Lopez, R. (2023). Long-term Effects of Altitude Training on Blood Rheological Properties in Elite Endurance Athletes. High Altitude Medicine & Biology, 24(2), 156-168.

8. Antonova, N., & Ivanov, I. (2023). Methods for assessing microcirculatory, hemorheological changes and oxygen transport in athletes of various sports disciplines. In Proceedings of the XXIV International Scientific Conference ‘FIS COMMUNICATIONS 2023’ (pp. 87-94).

9. El-Sayed, M. S. (1998). Effects of exercise and training on blood rheology. Sports Medicine, 26(5), 281-292.

10. Brun, J.-F., Varlet-Marie, E., Romain, A.-J., Guiraudou, M., & de Mauverger, E. R. (2013). Exercise hemorheology: Moving from old simplistic paradigms to a more complex picture. Clinical Hemorheology and Microcirculation, 55(1), 15-27.

11. Letcher, R. L., Pickering, T. G., Chien, S., & Laragh, J. H. (1981). Effects of exercise on plasma viscosity in athletes and sedentary normal subjects. Clinical Cardiology, 4(4), 172-179.

12. Tomschi, F., Bizjak, D., & Bloch, W. (2018). Deformability of different red blood cell populations and viscosity of differently trained young men in response to intensive and moderate running. Clinical Hemorheology and Microcirculation, 69(4), 503-514.

13. Cardinale, D. A., & Ekblom, B. (2018). Hyperoxia for performance and training. Journal of Sports Sciences, 36(13), 1515-1522.

14. Sperlich, B., Zinner, C., Hauser, A., Holmberg, H. C., & Wegrzyk, J. (2017). The impact of hyperoxia on human performance and recovery. Sports Medicine, 47(3), 429-438.

15. Teległów, A., Marchewka, J., Tota, Ł., Mucha, D., Ptaszek, B., Makuch, R., & Mucha, D. (2022). Changes in blood rheological properties and biochemical markers after participation in the XTERRA Poland triathlon competition. Scientific Reports, 12(1), 3349.

16. Mirek, W., Sudoł, G., Gradek, J., & Sławik, M. (2014). Estimation changes in intensity threshold under the influence 8-weeks middle distance running training through the Żołądź test. In Proceedings of the Atletika 2014 (pp. 178-185).

17. Baskurt, O. K., Hardeman, M. R., Rampling, M. W., & Meiselman, H. J. (2007). Handbook of Hemorheology and Hemodynamics. IOS Press.

18. Ernst, E. (1987). Influence of regular physical activity on blood rheology. European Heart Journal, 8(Suppl. G), 59-62.

19. Tripette, J., Hardy-Dessources, M.-D., Beltan, E., Alain, S., Jacqueline, B., Tawfik, C., et al. (2011). Endurance running trial in tropical environment: A blood rheological study. Clinical Hemorheology and Microcirculation, 47(4), 261-268.

20. Brun, J. F., Khaled, S., Raynaud, E., Bouix, D., Micallef, J. P., & Orsetti, A. (1998). The triphasic effects of exercise on blood rheology: Which relevance to physiology and pathophysiology? Clinical Hemorheology and Microcirculation, 19(2), 89-104.

21. Stephenson, L. A., & Kolka, M. A. (1988). Plasma volume during heat stress and exercise in women. European Journal of Applied Physiology and Occupational Physiology, 57(4), 373-381.

22. Lebrun, C. M., McKenzie, D. C., Prior, J. C., & Taunton, J. E. (1995). Effects of menstrual cycle phase on athletic performance. Medicine and Science in Sports and Exercise, 27(3), 437-444.

23. Bruinvels, G., Burden, R. J., McGregor, A. J., Ackerman, K. E., Dooley, M., Richards, T., & Pedlar, C. (2017). Sport, exercise and the menstrual cycle: where is the research? British Journal of Sports Medicine, 51(6), 487-488.

24. Martin, D., Sale, C., Cooper, S. B., & Elliott-Sale, K. J. (2018). Period prevalence and perceived side effects of hormonal contraceptive use and the menstrual cycle in elite athletes. International Journal of Sports Physiology and Performance, 13(7), 926-932.

25. Burke, L. M., Maughan, R. J., & Shirreffs, S. M. (2018). International Association of Athletics Federations Consensus Statement 2019: Nutrition for Athletics. International Journal of Sport Nutrition and Exercise Metabolism, 29(2), 73-84.

26. Roberts, S. S., Teo, W.-P., & Warmington, S. A. (2019). Sleep and chronobiology in elite athletes. Sleep Medicine Clinics, 14(1), 1-11.

27. Schmidt, W., & Prommer, N. (2020). Impact of smoking on endurance performance and blood parameters. Medicine & Science in Sports & Exercise, 52(1), 85-93.

28. Seiler, K. S. (2020). What is best practice for training intensity and duration distribution in endurance athletes? International Journal of Sports Physiology and Performance, 15(6), 825-838.

Published
2025-03-24
How to Cite
Li, P., Yang, Z., Ji, Y., Li, B., & Li, G. (2025). Effects of hyperoxic training on red blood cell deformability and mechanical properties in elite male endurance athletes: A randomized crossover study. Molecular & Cellular Biomechanics, 22(5), 590. https://doi.org/10.62617/mcb590
Issue
Vol. 22 No. 5 (2025)
Section
Article

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