Abstract
Repeated sprint training in hypoxia (RSH) has gained unprecedented popularity among the various strategies using hypoxia as an additional stimulus to improve performance. This case study reports the benefits of 150 repeated sprints in normobaric hypoxia over 10 days in a professional cyclist. After 3 weeks of endurance training in November, the cyclist performed five RSH sessions at a simulated altitude of 3,300 m on his own bicycle attached to an indoor trainer in a hypoxic chamber (FiO2 14.1 ± 0.1%, PiO2 94.6 ± 1.4 mm Hg). Each session consisted of four blocks of seven all-out sprints of 6 s interspersed with 14 s active recovery (for a total of 126 s per block). After 12 min of warm-up with a single isolated 6 s reference sprint, the sessions included a first and a second sprinting block with 4 min 54 s active recovery in-between. After 9 min 54 s active recovery including an isolated 6 s reference sprint, a third and a fourth block were performed with 4 min 54 s active recovery in-between, before an active cool-down of 9 min 54 s. The total duration was thus of 50 min per session for a total hypoxic exposure of 250 min exercising. Power output and heart rate were monitored at 1 Hz. Lactate concentration ([La]) and pulse oxygen saturation (SpO2) were measured at the start and end of each block during the first and fifth training session. Basal SpO2 was of 83% during session one and 85.5% during session five. When comparing the first and fifth training session, peak power increased for the best 1 s value (+8%) and the best 5 s average (+10%) to reach 1,041 W and 961 W, respectively. Average power for all blocks (including active recoveries) increased from 334 to 354 W with a similar average heart rate during the sessions (146'.min−1). Peak [La] was increased from 12.3 to 13.8 mmol.l−1. In conclusion, this case report illustrates a 10-days RSH intervention perceived as efficient in a professional cyclist and shown to improve total work (6-s sprints) produced for a similar physiological strain.
Highlights
Many athletes feel attracted to include altitude training interventions in their preparation anticipating additional performance gains in comparison to equivalent sea-level training
The good adherence to the training program and willingness to perform all-out sprints without pacing was confirmed by the consistent difference between the highest and lowest 1 s peak power attained during all blocks averaging −15.0 ± 2.4% over all training sessions
Our results indicate a strong additional stimulus of the hypoxic environment resulting in moderate hypoxia with the occurrence of some very low levels of oxygen saturation (e.g., 76%) during sprinting
Summary
Many athletes feel attracted to include altitude training interventions in their preparation anticipating additional performance gains in comparison to equivalent sea-level training Such benefits for elite athletes are still sharply debated (Millet and Brocherie, 2020). The ability to “sprint after having sprinted” was recently tested with greater reduction in a “final” 30 s sprint after a 1 h cycling trial if the latter includes multiple highintensity bouts (Etxebarria et al, 2019) These authors highlight the need to improve repeated sprint ability to optimize a final sprint and maintain a high performance level in competitive cycling
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
