Comparison of trained and untrained girls' blood buffering capacity response to three types of recovery during Repeated High-Intensity endurance test

Document Type : original article

Authors

1 Shahid Bahonar Campus, Faculty of Farhangian University, Hamadan, Iran

2 Department of Exercise Physiology, Faculty of Physical Education and Sport Science, Esfahan University. Esfahan, Iran

3 Shahid Maghsodi Campus, Faculty of Farhangian University, Hamadan, Iran

4 Department of Pathology, Faculty of Medical Science, Hamadan, Iran

Abstract

Purpose: Recovery after intense interval training plays an important role in improving athletic performance, while the type of recovery and exercise background can affect athletic performance. The aim of this study was to compare the Response of blood buffering capacity to three types of recovery during Repeated High-Intensity endurance test in trained and untrained girls' students of Farhangian University.
Methods: 30 female students of Farhangian University (mean age 22.49 ±.3 (year), weight 68.33 ± 7.31 (kg) and height 176.76 ± 8.32 (cm) were randomly selected in three recovery groups (active: N=10, passive: N=10, Stretching: N=10) randomly. The Subjects underwent three types of recovery during the repeated high-intensity endurance test after evaluating the maximum oxygen consumption according to a specific pattern in a crossover methods, three days in a week. Arterial blood sample were taken measured before and immediately after the test and buffering capacity and carnosine were analyzed by ABG and ELISA techniques. After 8-eight weeks of aerobic exercise (65-80% of maximal heart rate), the test and blood sampling were repeated with the same pre-test and at the same time.
Results: In untrained girls, only significant difference was found between stretching and active recovery for oxygen saturation, and in trained girls' there was a significant increase in oxygen saturation for active and passive recovery. Significant increase in blood acidity, bicarbonate, base buffers and carnosine was observed in trained girls by active recovery (P ≤ 0.05).
Conclusion: The results show that the response of buffering capacity to the three types of recovery was significantly higher in trained subjects. Which is more notable with active recovery.
 

Keywords

References

  1. Ahmaidi S, Granier P, Taoutaou Z, Mercier J, Dubouchaud H, Prefaut C. Effects of active recovery on plasma lactate and anaerobic power following repeated intensive exercise. Medicine and science in sports and exercise. 1996;28(4):450-6.
  2. Spierer D, Goldsmith R, Baran D, Hryniewicz K, Katz S. Effects of active vs. passive recovery on work performed during serial supramaximal exercise tests. International journal of sports medicine. 2004;25(02):109-14.
  3. Nalbandian HM, Radak Z, Takeda M. Active Recovery between Interval Bouts Reduces Blood Lactate While Improving Subsequent Exercise Performance in Trained Men. Sports. 2017;5(2):40.
  4. Toubekis AG, Douda HT, Tokmakidis SP. Influence of different rest intervals during active or passive recovery on repeated sprint swimming performance. European journal of applied physiology. 2005;93(5-6):694-700.
  5. Jougla Aa, Micallef J, Mottet D. Effects of active vs. passive recovery on repeated rugby-specific exercises. Journal of Science and Medicine in Sport. 2010; 13(3): 350-355.
  6. Fashi M, A k. The response of blood buffering capacity and H+ regulation to three types of recovery during repeated high-intensity endurance training. Research in Sport Medicine and Technology. 2011;9(2):27-40.
  7. Sairyo K, Iwanaga K, Yoshida N, Mishiro T, Terai T, Sasa T, et al. Effects of active recovery under a decreasing work load following intense muscular exercise on intramuscular energy metabolism. International Journal of Sports Medicine. 2003;24(03):179-82.
  8. Robergs R. Ghiasvand F, Parker D. Biochemistry of exercise-induced metabolic acidosis Am J Physiol Regul Integr Comp Physiol. 2004;287:R502-R16.
  9. Devlin J, Paton B, Poole L, Sun W, Ferguson C, Wilson J, et al. Blood lactate clearance after maximal exercise depends on active recovery intensity. Journal of Sports Medicine and Physical Fitness. 2014;54(3):271-8.
  10. Keller C, Keller P, Giralt M, Hidalgo J, Pedersen BK. Exercise normalises overexpression of TNF-α in knockout mice. Biochemical and biophysical research communications. 2004;321(1):179-82.
  11. Dunnett M, Harris R, Dunnett C, Harris P. Plasma carnosine concentration: diurnal variation and effects of age, exercise and muscle damage. Equine veterinary journal. 2002;34(S34):283-7.
  12. Varanoske AN, Stout JR, Hoffman JR. Effects of β-Alanine Supplementation and Intramuscular Carnosine Content on Exercise Performance and Health. Nutrition and Enhanced Sports Performance: Elsevier; 2019. p. 327-44.
  13. Tomlin DL, Wenger HA. The relationship between aerobic fitness and recovery from high intensity intermittent exercise. Sports Medicine. 2001;31(1):1-11.
  14. Bishop D, Edge J, Goodman C. Muscle buffer capacity and aerobic fitness are associated with repeated-sprint ability in women. European journal of applied physiology. 2004;92(4-5):540-7.
  15. Algul S, Ozcelik O, Yilmaz B. Evaluation of relationship between aerobic fitness level and range of isocapnic buffering periods during incremental exercise test. Cell Mol Biol (Noisy-le-grand). 2017;63(3):78-82.
  16. Juel C, Klarskov C, Nielsen JJ, Krustrup P, Mohr M, Bangsbo J. Effect of high-intensity intermittent training on lactate and H+ release from human skeletal muscle. American Journal of Physiology-Endocrinology and Metabolism. 2004;286(2):E245-E51.
  17. Edge J, Bishop D, Goodman C. The effects of training intensity on muscle buffer capacity in females. European journal of applied physiology. 2006;96(1):97-105.
  18. Corder KP, Potteiger JA, Nau KL, FIGONI SE, Hershberger SL. Effects of active and passive recovery conditions on blood lactate, rating of perceived exertion, and performance during resistance exercise. The Journal of Strength & Conditioning Research. 2000;14(2):151-6.
  19. Dupont G, Blondel N, Berthoin S. Performance for short intermittent runs: active recovery vs. passive recovery. European journal of applied physiology. 2003;89(6):548-54.
  20. Draper N, Bird EL, Coleman I, Hodgson C. Effects of active recovery on lactate concentration, heart rate and RPE in climbing. Journal of sports science & medicine. 2006;5(1):97.
  21. Mota MR, Dantas RAE, Oliveira-Silva I, Sales MM, da Costa Sotero R, Venâncio PEM, et al. Effect of self-paced active recovery and passive recovery on blood lactate removal following a 200 m freestyle swimming trial. Open access journal of sports 2017;8:155.
  22. Hanson NJ, Scheadler CM, Lee TL, Neuenfeldt NC, Michael TJ, Miller MG. Modality determines VO2max achieved in self-paced exercise tests: validation with the Bruce protocol. European journal of applied physiology. 2016;116(7):1313-9.
  23. Jones N. Hydrogen ion balance during exercise. Clinical Science. 1980;59(2):85-91.
  24. Cairns SP. Lactic acid and exercise performance. Sports medicine. 2006;36(4):279-91.
  25. Péronnet F, Aguilaniu B. Lactic acid buffering, nonmetabolic CO2 and exercise hyperventilation: a critical reappraisal. Respiratory physiology & neurobiology. 2006;150(1):4-18.
  26. Bishop D, Edge J, Thomas C, Mercier J. Effects of high-intensity training on muscle lactate transporters and postexercise recovery of muscle lactate and hydrogen ions in women. American Journal of Physiology-Regulatory, Integrative and Comparative Physiology. 2008;295(6):R1991-R8.
  27. Keller MA, Zylstra A, Castro C, Turchyn AV, Griffin JL, Ralser M. Conditional iron and pH-dependent activity of a non-enzymatic glycolysis and pentose phosphate pathway. Science advances. 2016;2(1):e1501235.
  28. Weston AR, Myburgh KH, Lindsay FH, Dennis SC, Noakes TD, Hawley JA. Skeletal muscle buffering capacity and endurance performance after high-intensity interval training by well-trained cyclists. European journal of applied physiology and occupational physiology. 1996;75(1):7-13.
  29. Gibala MJ. Physiological adaptations to low-volume high-intensity interval training. Sports Science Exchange. 2015;28(139):1-6.
  30. Astorino TA, Edmunds RM, Clark A, Gallant R, King L, Ordille GM, et al. Change in maximal fat oxidation in response to different regimes of periodized high-intensity interval training (HIIT). European journal of applied physiology. 2017;117(4):745-55.
  31. Oliveira L, Salles Painelli V, Nemezio K, Gonçalves L, Yamaguchi G, Saunders B, et al. Chronic lactate supplementation does not improve blood buffering capacity and repeated high‐intensity exercise. Scandinavian journal of medicine & science in sports. 2017;27(11):1231-9.
  32. Kenney WL, Wilmore JH, Costill DL. Physiology of sport and exercise: Human kinetics; 2015.
  33. McGinley C, Bishop DJ. Influence of training intensity on adaptations in acid/base transport proteins, muscle buffer capacity, and repeated-sprint ability in active men. Journal of Applied Physiology. 2016;121(6):1290-305.
  34. Abe T, Yasuda T, Midorikawa T, Sato Y, CF K, Inoue K, et al. Skeletal muscle size and circulating IGF-1 are increased after two weeks of twice daily “KAATSU” resistance training. International Journal of KAATSU Training Research. 2005;1(1):6-12.
  35. Kisaka T, Cox TA, Dumitrescu D, Wasserman K. CO2 pulse and acid-base status during increasing work rate exercise in health and disease. Respiratory physiology & neurobiology. 2015;218:46-56.
  36. Sahlin K, Alvestrand A, Brandt R, Hultman E. Intracellular pH and bicarbonate concentration in human muscle during recovery from exercise. Journal of Applied Physiology. 1978;45(3):474-80.
  37. Del Coso J, Hamouti N, Aguado-Jimenez R, Mora-Rodriguez R. Restoration of blood pH between repeated bouts of high-intensity exercise: effects of various active-recovery protocols. European journal of applied physiology. 2010;108(3):523-32.
  38. Wagner PD. The physiological basis of pulmonary gas exchange: implications for clinical interpretation of arterial blood gases. European Respiratory Journal. 2015;45(1):227-43.
  39. Sale C, Artioli GG, Gualano B, Saunders B, Hobson RM, Harris RC. Carnosine: from exercise performance to health. Amino acids. 2013;44(6):1477-91.
  40. Varanoske AN, Hoffman JR, Church DD, Coker NA, Baker KM, Dodd SJ, et al. β-Alanine supplementation elevates intramuscular carnosine content and attenuates fatigue in men and women similarly but does not change muscle l-histidine content. Nutrition research. 2017;48:16-25.
  41. Baguet A, Everaert I, De Naeyer H, Reyngoudt H, Stegen S, Beeckman S, et al. Effects of sprint training combined with vegetarian or mixed diet on muscle carnosine content and buffering capacity. European journal of applied physiology. 2011;111(10):2571-80.
  42. de Oliveira LF, da Silva RP, de Salles Painelli V, Carvalho VH, de Oliveira AHS, Saunders B, et al. Relationship between skeletal muscle carnosine content and cycling sprint performance. Journal of Science and Cycling. 2019;8(2):48.
  43. Artioli GG, Gualano B, Smith A, Stout J, Lancha Jr AH. Role of beta-alanine supplementation on muscle carnosine and exercise performance. Med Sci Sports Exerc. 2010;42(6):1162-73.

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History

  • Receive Date: 08 January 2020
  • Revise Date: 09 April 2020
  • Accept Date: 20 April 2020
  • First Publish Date: 23 September 2021
  • Publish Date: 23 September 2021

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