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Climatic heat stress and performance in the Wingate Anaerobic Test

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Summary

To determine climatic effects on performance of the Wingate Anaerobic Test, 28 children (10.2–12.2 years old) were each tested in three different climates: Neutral (22–23‡ C, 55–60% R.H.), hot-dry (38–39‡ C, 25–30% R.H.), and warm-humid (30‡ C, 85–90% R.H.). The test is an all-out 30 s cycle-ergometer-pedalling in which mean as well as peak power outputs are determined. The children stayed in the climatic chamber for 45 min prior to the test. Mean power, relative to body weight, was higher in the boys after the warm-humid exposure compared with the hot-dry one (P<0.05). No other differences were found. Inter-climate correlations of weight-relative power outputs were 0.83–0.92 and 0.82–0.86 for mean power in the girl and boy groups, respectively, and 0.33–0.72 and 0.49–0.75 for peak power, in the same order. The corresponding values for absolute power outputs were always higher. Reasons why the single detected inter-climate difference is likely to have been a happenstance are discussed, and it is suggested that comparable environmental exposures do not appreciably affect performance of the Wingate Anaerobic Test by children and young adolescents. The practicality and reliability of this test is, therefore, well maintained in “field situations” where climate cannot be strictly controlled.

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References

  • Asmussen E, Böje O (1945) Body temperature and capacity for work. Acta Physiol Scand 10: 1–22

    Google Scholar 

  • Bar-Or O (1980) Climate and the exercising child — a review. Int J Sports Med (in press)

  • Bar-Or O, Dotan R, Inbar O (1977) A 30 s all-out ergometric test — its reliability and validity for anaerobic capacity. Isr J Med Sci (Abstr) 13: 326–327

    Google Scholar 

  • Bar-Or O, Inbar O (1978) Relationships among anaerobic capacity, sprint and middle distance running of school children. In: Sherpard RJ, Lavallée H (eds) Physical fitness assessment — principles, practice, and application. Thomas, Springfield, pp 142–147

    Google Scholar 

  • Clarke DH, Royce J (1962) Rate of muscle tension development and release under extreme temperatures. Int Z Angew Physiol Einschl Arbeitsphysiol 19: 330–335

    Google Scholar 

  • Edwards RHT, Harris RC, Hultman E, Kaijser L, Koh D, Nordesjö L-O (1972) Effects of temperature on muscle energy, metabolism and endurance during successive isometric contractions sustained to fatigue, of the quadriceps muscle in man. J Physiol (Lond) 220: 335–352

    Google Scholar 

  • Frank BD (1972) Physical warm-up. In: Morgan WP (ed) Ergogenic aids and muscular performance. Academic Press, London New York, pp 159–191

    Google Scholar 

  • Hill AV (1956) The design of muscles. Br Med Bull 12: 165–166

    Google Scholar 

  • Inbar O, Bar-Or O (1975) The effects of intermittent warm-up on 7–9 year-old boys. Eur J Appl Physiol 34: 81–89

    Google Scholar 

  • Inbar O, Bar-Or O (1977) Relationship of anaerobic and aerobic arm and leg capacities to swimming performance of 8–12-year-old children. In: Shepard RJ, Lavalée H (eds) Frontiers of activities and child health. Pelican, Quebec, pp 283–292

    Google Scholar 

  • Inbar O, Dotan R, Bar-Or O (1976) Aerobic and anaerobic components of a 30 s supramaximal cycling test. Med Sci Sports (Abstr) 8: 51

    Google Scholar 

  • King PG, Mendryk S, Reid DC, Kelly R (1970) The effect of actively increased muscle temperature on grip strength. Med Sci Sports 2: 172–175

    Google Scholar 

  • Mathews DK, Stacy RW, Hoover GN (1964) Physiology of muscular activity and exercise. Ronald Press, New York, pp 285–286

    Google Scholar 

  • Rowell LB, Brengelmann GL, Murray JA, Kraning II, KK, Kusimi F (1969) Human metabolic responses to hyperthermia during mild to maximal exercise. J Appl Physiol 26: 395–402

    Google Scholar 

  • Saltin B (1964) Aerobic and anaerobic work capacity after dehydration. J Appl Physiol 19: 1114–1118

    Google Scholar 

  • Saltin B, Hermansen L (1966) Esophageal, rectal, and muscle temperature during exercise. J Appl Physiol 21: 1757–1762

    Google Scholar 

  • Williams CG, Bredell GAG, Wyndham CH, Strydom NB, Morrison JF, Peter J, Fleming PW, Ward JS (1962) Circulatory and metabolic reactions to work in heat. J Appl Physiol 17: 625–638

    Google Scholar 

  • Wyndham CH, Strydom NB, Van Rensburg AJ, Benade AJS, Heyns AJ (1970) Relation between VO2 max and body temperature in hot humid air conditions. J Appl Physiol 29: 45–50

    Google Scholar 

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This study was supported by the Sports and Physical Education Authority, Ministry of Education and Culture, Israel

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Dotan, R., Bar-Or, O. Climatic heat stress and performance in the Wingate Anaerobic Test. Europ. J. Appl. Physiol. 44, 237–243 (1980). https://doi.org/10.1007/BF00421623

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  • DOI: https://doi.org/10.1007/BF00421623

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