Authors: Thanura Abeywardena

Abstract:

This study recognized the effectiveness of cold-water immersion recovery post short-term exhaustive exercise. The purpose of this study was to understand if 16-20 °C of cold-water immersion would be beneficial in a tropical environment to achieve an optimal recovery in sprint swim performance in comparison to 10-15 °C of water immersion. Two 100 m-sprint swim performance times were measured along with blood lactate (BLa), heart rate (HR) and rate of perceived exertion (RPE) in a 25 m swimming pool with full body head out horizontal water immersions of 10-15 °C, 16-20 °C and 29-32 °C (pool temperature) for 10 minutes followed by 5 minutes of seated passive rest outside; in between the two swim performances. 10 well-trained adult swimmers (5 male and 5 female) within the top twenty in the Sri Lankan nationals swimming championships in 100m Butterfly and Freestyle in the years 2020 & 2021 volunteered for this study. One-way ANOVA analysis (p < 0.05) suggested performance time, BLa and HR had no significant differences between the three conditions after the second sprint, however RPE was significantly different with p = 0.034 between 10-15 °C and 16-20 °C immersion conditions. The study suggested that the recovery post the two cold-water immersion conditions were similar in terms of performance and physiological factors however the 16-20 °C temperature had a better “feel good” factor post sprint 2. Further study is recommended as there was participant bias with the swimmers not reaching optimal levels in sprint 1. Therefore, they might have been possibly fully recovered before sprint 2 invalidating the physiological effect of recovery.

Keywords: Hydrotherapy, blood lactate, fatigue, recovery, sprint-performance, sprint-swimming.

Procedia APA BibTeX Chicago EndNote Harvard JSON MLA RIS XML ISO 690 PDF Downloads 160

References:

[1] D.B. Pyne, and R.L. Sharp, “Physical and energy requirements of competitive swimming events,” International journal of sport nutritionand exercise metabolism, vol.24(4), pp.351-359, Aug. 2014.
[2] S.D. Felix, T.M. Manos, A.T. Jarvis, B.E. Jensen and S.A. Headley, “Swimming performance following different recovery protocols in female collegiate swimmers,” Journal of Swimming Research, vol.12, pp.1-6, Sep. 1997.
[3] S.L. Halson, “Does the time frame between exercise influence the effectiveness of hydrotherapy for recovery?,” International journal of sports physiology and performance, vol6(2), pp.147-59, June. 2011.
[4] M.J. Hopwood, K. Graham and K.B. Rooney, “Creatine supplementation and swim performance: a brief review,” Journal of Sports Science & Medicine, vol 5(1), pp. 10, March. 2006.
[5] J. Hirvonen, A. Nummela, H. Rusko, S. Rehunen and M, Härkönen. “Fatigue and changes of ATP, creatine phosphate, and lactate during the 400-m sprint,” Canadian Journal of Sport Science, vol 17(1), pp.141-144 June. 1992.
[6] A.G. Toubekis, A. Tsolaki, I. Smilios, H.T. Douda, T. Kourtesis and S.P. Tokmakidis, “Swimming performance after passive and active recovery of various durations,” International Journal of Sports Physiology and Performance, vol 3(3), pp. 375-386, Sep. 2008.
[7] P. Pelayo, I. Mujika, M. Sidney and J.C. Chatard, “Blood lactate recovery measurements, training, and performance during a 23-week period of competitive swimming,” European journal of applied physiology and occupational physiology, vol 74(1), pp. 107-113, Aug. 1996.
[8] K.D. Beckett and K. Steigbigel, “Effects of warm down techniques on the removal of lactate acid following maximal human performance,” J Swim Res, vol 9, pp.32-35, 1993.
[9] C.R. Abbiss and P.B. Laursen, “Models to explain fatigue during prolonged endurance cycling,’ Sports medicine, vol 35(10), pp. 865-898, Oct. 2005.
[10] P.A Bishop, E. Jones and A.K. Woods, “Recovery from training: a brief review: brief review,” The Journal of Strength & Conditioning Research, vol 22(3), pp. 1015-1024, May. 2008.
[11] E. Lätt, J. Jürimäe, J. Mäestu, P. Purge, R. Rämson, K. Haljaste, K.L. Keskinen, F.A. Rodriguez and T. Jürimäe, “Physiological, biomechanical and anthropometrical predictors of sprint swimming performance in adolescent swimmers,” Journal of sports science & medicine, Vol 9(3), pp.398, Sep. 2010.
[12] F.B. Neric, W.C Beam, L.E Brown and L.D Wiersma, “Comparison of swim recovery and muscle stimulation on lactate removal after sprint swimming,” The Journal of Strength & Conditioning Research, vol 23(9), pp. 2560-2567, Dec. 2009.
[13] K. Sahlin, “Muscle fatigue and lactic acid accumulation,”. Acta physiologica Scandinavica. Supplementum, vol 556, pp.83-91, Jan. 1986.
[14] I.M. Wilcock, J.B. Cronin and W.A Hing, “Physiological response to water immersion,” Sports medicine, vol 36(9), pp. 747-65, Sep. 2006.
[15] D.L. Tomlin and H.A Wenger, “The relationship between aerobic fitness and recovery from high intensity intermittent exercise,” Sports Medicine, Vol 31(1), pp.1-11, Jan. 2001.
[16] M. Jemni, W.A Sands, Friemel and P. Delamarche, “Effect of active and passive recovery on blood lactate and performance during simulated competition in high level gymnasts,” Canadian journal of applied physiology, vol. 28(2), pp. 240-256, April. 2003.
[17] Z. Rezaee, F. Esfarjani, and S.M. Marandi, “Which temperature during the water immersion recovery is best after a sprint swimming,”WorldAppl Sci J, vol 16(10), pp.1403-1408. 2012.
[18] I. Wilcock, “The effect of water immersion, active recovery and passive recovery on repeated bouts of explosive exercise and blood plasma fraction,” Doctoral. dissertation, Auckland University of Technology, New Zealand, 2005.
[19] A. Bosak, P. Bishop, J. Green and G. Hawver, “Impact of cold water immersion on 5km racing performance,” The Sport Journal, Vol 12(2), March. 2009.
[20] N.G. Versey, S.L. Halson and B.T. Dawson, “Water immersion recovery for athletes: effect on exercise performance and practical recommendations,” Sports medicine, vol 43(11), pp.1101-1130, June.2013.
[21] J.M. Stephens, S. Halson, J. Miller, G.J. Slater and C.D. Askew, “Cold- water immersion for athletic recovery: one size does not fit all,” International Journal of Sports Physiology and Performance, vol 12(1), pp.2-9, Jan. 2017.
[22] J.J. Peiffer, C.R. Abbiss, G. Watson, K. Nosaka and P.B. Laursen, “Effect of cold water immersion on repeated 1-km cycling performance in the heat,”Journal of science and medicine in sport, vol. 13(1), pp.112-116, Jan. 2010.
[23] J. Parouty, H. Al Haddad, M. Quod, P.M. Leprêtre, S. Ahmaidi and M. Buchheit, “Effect of cold water immersion on 100-m sprint performance in well- trained swimmers,” European journal of applied physiology, vol.109(3), pp.483-490, June. 2010.