Increased maximal oxygen uptake after sprint-interval training is mediated by central hemodynamic factors as determined by right heart catheterization.

There is a lack of knowledge regarding the contribution of central and peripheral factors to the increases in VO following sprint-interval training (SIT). This study investigated the importance of maximal cardiac output (Q ) in relation to VO improvements following SIT and the relative importance of the hypervolemic response on Q and VO . We also investigated if systemic O extraction increased with SIT as has been previously suggested. Healthy men and women (n = 9) performed 6 weeks of SIT. State-of-the-art measurements: right heart catheterization, carbon monoxide rebreathing and respiratory gas exchange analysis were used to assess Q , arterial O content (c O ), mixed venous O content (c O ), blood volume (BV) and VO before and after the intervention. In order to assess the relative contribution of the hypervolemic response to the increases in VO , BV was reestablished to pre-training levels by phlebotomy. Following the intervention, VO , BV and Q increased by 11% (p<0.001), 5.4% (p = 0.013), and 8.8% (p = 0.004) respectively. c O decreased by 12.4% (p = 0.011) and systemic O extraction increased by 4.0% (p = 0.009) during the same period, both variables were unaffected by phlebotomy (p = 0.589 and p = 0.548, respectively). After phlebotomy, VO and Q reverted back to pre-intervention values (p = 0.064 and p = 0.838 respectively) and were significantly lower compared to post-intervention (p = 0.016 and p = 0.018 respectively). The decline in VO2 after phlebotomy was linear to the amount of blood removed (p = 0.007, R = -0.82). The causal relationship between BV, Q and VO shows that the hypervolemic response is a key mediator of the increases in VO following SIT. KEY POINTS: Sprint-interval training (SIT) is an exercise model involving supramaximal bouts of exercise interspersed with periods of rest known for its efficiency in improving maximal oxygen uptake (VO ). In contrast to the commonly accepted view where central hemodynamic adaptations are considered to be the key mediators of increases in VO there have been propositions highlighting peripheral adaptations as the main mediators in the context of SIT-induced changes in VO . By combining right heart catheterization, carbon monoxide rebreathing and phlebotomy this study shows that increases in maximal cardiac output due to the expansion of the total blood volume is a major explanatory factor for the improvement in VO following SIT. With a smaller contribution from improved systemic oxygen extraction. The present work not only clarifies a controversy in the field by using state-of-the-art methods, but also encourages future research to investigate regulatory mechanisms that could explain how SIT can lead to similar improvements in VO and maximal cardiac output to what has previously been reported for traditional endurance exercise. Abstract figure legend This study aimed to understand the factors contributing to increases in maximal oxygen uptake (VO ) after sprint-interval training (SIT). The study involved 9 healthy subjects who completed 6 weeks of SIT. Measurements were taken before and after the intervention to assess factors such as maximal cardiac output (Q ), arterial and mixed venous oxygen content (c O and c O ), blood volume (BV), and VO . To determine the importance of the hypervolemic response on Q and VO , BV was reduced to pre-training levels through phlebotomy. Following the intervention, VO , BV, and Q increased, while c O decreased, and systemic O extraction increased. After phlebotomy, VO and Q decreased to pre-intervention levels, and were significantly lower than post-intervention values. The study suggests that the hypervolemic response is a key factor in the increases in VO following SIT. This article is protected by copyright. All rights reserved.