Soetanto Hartono¹, Achmad Widodo¹, Himawan Wismanadi¹, Gulbuldin Hikmatyar¹

¹Surabaya State University, Faculty of Sport Sciences, Surabaya, Indonesia

The Effects of Roller Massage, Massage, and Ice Bath on Lactate Removal and Delayed Onset Muscle Soreness

Sport Mont 2019, 17(2), 111-114 | DOI: 10.26773/smj.190620

Abstract

The purpose of the study was to investigate the effects of rolling massage, massage, and ice bath on lactate removal and delayed onset muscle soreness. Thirty students of Faculty of Sport Sciences of third semester were randomly selected and assigned to three groups, roller massage, massage, and ice bath group. All groups were doing Running-based Anaerobic Sprint Test (RAST) after 10 minute warm up. Eight minutes after RAST, all students were examined their blood lactate using blood lactate analyzer. The roller massage group was treated using foam roller for 5 minutes, , the massage group was massaged for 5 minutes, the ice bath group were put in 10 degree cold water for 5 minutes, then their blood lactate were reexamined. The normality test of roller massage is .022, and homogeinity test p=.133, so the data was analized using nonparametric Kruskal Wallis. Contrary to results of other studies, lactate removal tends to be the most effective in ice bath treatment (17.40) compared with massage treatment (16.65), and roller massage (12.45), and reduction in Delayed Onset Muscle Soreness (DOMS) tends to be most effective in ice bath treatment (12.25) compared with massage treatment (13.95), and roller massage (20.30) eventhough non significant (p=.399). Vasoconstriction effect of ice bath made a faster lactate removal, physique trait also might have an effect. Cooling effect of ice bath has an effective analgetic effect.

Keywords

massage, roller massage, ice bath, blood lactate, Delayed Onset Muscle Soreness (DOMS)

View full article
(PDF – 114KB)

References

Butterfield, T.A., Best, T.M., & Merrick, M.A. (2006). The dual roles of neutrophils and macrophages in inflammation: a critical balance between tissue damage and repair. J Athl Train, 41(4), 457–465.

Butterfield, T.A., Zhao, Y., Agarwal, S., Haq, F., & Best, T.M. (2008). Cyclic compressive loading facilitates recovery after eccentric exercise. Med Sci Sports Exerc, 40(7), 1289–1296.

Butterfield, T.A. (2010). Eccentric exercise in vivo: strain-induced muscle damage and adaptation in a stable system. Exerc Sport Sci Rev, 38(2), 51–60.

Cheung, K., Hume, P.A., & Maxwell, L. (2003). Delayed Onset Muscle Soreness. Treatment Strategies and Performance Factors. Sports Medicine. Volume, 33, 145–164.

Curtis, A.S.G., & Sheehar, G.M. (1978). The Control of Cell Division by Tension or Diffusion; Nature, 274, 52-53.

Draper, N. & Whyte, G. (1997). Here’s a new running based test of anaerobic performance for which you need only a stopwatch and a calculator. Peak Perfor-mance, 96, 3-5.

Dupuy, O., Douzi, W., Theurot, D., Bosquet, L., & Dugué, B. (2018). An Evidence-Based Approach for Choosing Post-exercise Recovery Techniques to Reduce Markers of Muscle Damage, Soreness, Fatigue, and Inflammation: A Systematic Review with Meta-Analysis. Front Physiol, 26, 9-403.

Fridén, J., Sfakianos, P.N., & Hargens. A.R. (1986). Muscle soreness and intramuscular fluid pressure: comparison between eccentric and concentric load. J Appl Physiol, 61(6), 2175-9.

Gehlsen, G.M., Ganion, L.R., & Helllfst, R. (1999). Fibroblast Responses to Variation in Soft Tissue Mobilization Pressure. Med. Sci. Sports Med, 31(4), 531-535.

Harlinda. (2014). Delayed Onset Muscle soreness. Jakarta:LPP FKUI.

Ihsan, M., Watson, G., Abbiss, C.R. (2016). What are the Physiological Mechanisms for Post-Exercise Cold Water Immersion in the Recovery from Prolonged Endurance and Intermittent Exercise? Sports Med., 46(8), 1095-109.

Ingram, J., Dawson, B., Goodman, C., Wallman, K., & Beilby, J. (2009). Effect of water immersion methods on post-exercise recovery from simulated team sport exercise. J Sci Med Sport, 12(3), 417-21.

Jain, M.K., Berg, R-A., & Tandon, G.P. (1990). Mechanical Stress and Cellular Metabolism in Living Soft Tissue Composites. Biomaterials, 34, 465-471.

Mansour, A., Fox, C.A., Akil, H., & Watson, S.J. (1995). Opioid receptor mRNA expression in the rat CNS: anatomical and functional implication. Trends Neurosci, 18, 22-29.

Sellwood, K.L., Brukner, P., Williams, D., Nicol, A., & Hinman, R. (2007). Ice-water immersion and delayed-onset muscle soreness: a random-ised controlled trial.B r J Sports Med, 41, 392–7.

Shirinsky, V.P., Antonov, A.S., Birukov, K.G., Sobolevsky, A.V., Romanov, Y.A., Kabaeva, N.V., Antonova, G.N., & Smirnov, V.N. (1989). Mechano-Chemical Control of Human Endothelium Orientation and Size. J. Cell Biol., 109, 331-339.

Sofroniev, M.V. (1983). Vasopresin and Oxytosin in the mammalian brain and spinal cord. Trends Neurosci, 6,167-172.

Stephens, J.M., Halson, S., Miller, J., Slater, G.J., & Askew, C.D. (2017). Cold-Water Immersion for Athletic Recovery: One Size Does Not Fit All. Int J Sports Physiol Perform, 12(1), 2-9.

Uvnas-Moberg, K., Bruzeliu, G., Alster, P., & Lundeberg, T. (1993). The antinociceptive effect of non-noxious sensory stimulation is mediated partly through oxytocinergic mechanism. Acta Physiol Scand, 149, 199-204.

Versey, N.G., Halson, S.L., & Dawson, B.T. (2013). Water immersion recovery for athletes: effect on exercise performance and practical rec-ommendations. Sports Med, 43(11), 1101-30.

Wilcock, I.M., Cronin, J.B., & Hing, W.A. (2006). Physiological response to water immersion: a method for sport recovery? Sports Med, 36(9), 747-65.

Waters-Banker, C., Dupont-Versteegden, E.E., Kitzman, P.H., & Butterfield, T.A. (2014). Investigating the Mechanisms of Massage Efficacy: The Role of Mechanical Immunomodulation. J Athl Train, 49(2), 266–273.