Abstract
Chronic exposure to a stressor elicits adaptations enhancing the tolerance to that stressor. These adaptive responses might also improve tolerance under less stressful conditions. For example, historically there has been much interest in the adaptive responses to high-altitude, or hypoxia, and their ergogenic potential under sea-level, or normoxic, conditions. In contrast, the influence of the adaptive responses to heat on exercise under cooler conditions has received relatively little interest. Heat acclimation/acclimatization (HA) is known to increase work capacity in hot environments. Yet, aerobic exercise performance can progressively deteriorate as ambient temperature increases beyond ~10 °C, indicating a thermal limitation even under relatively cool conditions. The improved thermoregulatory capability induced by HA might attenuate this thermal decrement in a manner similar to that seen when exposed to hotter temperatures. Moreover, the suite of adaptations elicited by HA has the potential to increase maximal oxygen uptake, lactate threshold and economy, and thus may be ergogenic even under conditions where performance is not thermally limited. Indeed, evidence is now emerging to support an ergogenic effect of HA but the number of studies is limited and in some instances lack appropriate control, are confounded by methodological limitations, or do not address the mechanisms of action. Nevertheless, these tantalising insights into the ergogenic potential of heat will likely generate considerable interest in this new ‘hot topic’. Future research will need to employ well-designed studies to clarify the exercise conditions under which ergogenic effects of HA are apparent, to elucidate the precise mechanisms, and to optimise HA strategies for performance.
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Acknowledgments
Jo Corbett, Rebecca Neal, Heather Lunt and Michael Tipton have no conflicts of interest to declare. Rebecca Neal receives a bursary joint-funded by UK Sport and the University of Portsmouth.
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Corbett, J., Neal, R.A., Lunt, H.C. et al. Adaptation to Heat and Exercise Performance Under Cooler Conditions: A New Hot Topic. Sports Med 44, 1323–1331 (2014). https://doi.org/10.1007/s40279-014-0212-8
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DOI: https://doi.org/10.1007/s40279-014-0212-8