Abstract
Exercise-induced hypoxemia (EIH) is well-described in endurance-trained athletes during both maximal and submaximal exercise intensities. Despite the drop in oxygen (O2) saturation and provided that training volumes are similar, athletes who experience EIH nevertheless produce the same endurance performance in normoxia as athletes without EIH. This lack of a difference prompted trainers to consider that the phenomenon was not relevant to performance but also suggested that a specific adaptation to exercise is present in EIH athletes. Even though the causes of EIH have been extensively studied, its consequences have not been fully characterized. With the development of endurance outdoor activities and altitude/hypoxia training, athletes often train and/or compete in this stressful environment with a decrease in the partial pressure of inspired O2 (due to the drop in barometric pressure). Thus, one can reasonably hypothesize that EIH athletes can specifically adapt to hypoxemic episodes during exercise at altitude. Although our knowledge of the interactions between EIH and acute exposure to hypoxia has improved over the last 10 years, many questions have yet to be addressed. Firstly, endurance performance during acute exposure to altitude appears to be more impaired in EIH vs. non-EIH athletes but the corresponding physiological mechanisms are not fully understood. Secondly, we lack information on the consequences of EIH during chronic exposure to altitude. Here, we (i) review research on the consequences of EIH under acute hypoxic conditions, (ii) highlight unresolved questions about EIH and chronic hypoxic exposure, and (iii) suggest perspectives for improving endurance training.
Highlights
For many years, cardiovascular responses and muscle metabolism were the only acknowledged limiting factors in exercise performance
exercise-induced hypoxemia (EIH) is typically observed during exercises in a laboratory at sea level
Studies have suggested that EIH reduces performance and induces fatigue (Powers et al, 1988; Romer et al, 2006)
Summary
Cardiovascular responses and muscle metabolism were the only acknowledged limiting factors in exercise performance. The phenomenon involves a decrease in arterial oxygen pressure (PaO2) and a concomitant drop in arterial oxygen saturation (SaO2) between rest and maximal exercise This hypoxemia is associated with abnormal gas exchange, as reflected by an increase in the alveolo-arterial oxygen pressure difference [D(Aa)O2] (Dempsey and Wagner, 1999; Prefaut et al, 2000). Since PaO2 and SaO2, together with the hemoglobin concentration, impact the arterial O2 content (CaO2), the oxygen (O2) supply to the muscles and aerobic exercise performance at sea level are impacted. In this context, EIH has attracted interest from sports scientists and physiologists
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