The physiological mechanisms of performance enhancement with sprint interval training differ between the upper and lower extremities in humans
Permanent link
https://hdl.handle.net/10037/10610Date
2016-09-30Type
Journal articleTidsskriftartikkel
Peer reviewed
Author
Zinner, Christoph; Morales-Alamo, David; Ørtenblad, Niels; Larsen, Filip J; Schiffer, Tomas A; Willis, Sarah J; Gelabert-Rebato, Miriam; Perez-Valera, Mario; Boushel, Robert; Calbet, Jose AL; Holmberg, Hans-ChristerAbstract
To elucidate the mechanisms underlying the differences in adaptation of arm and leg
muscles to sprint training, over a period of 11 days 16 untrained men performed six sessions of 4–6
× 30-s all-out sprints (SIT) with the legs and arms, separately, with a 1-h interval of recovery.
Limb-specific VO2peak, sprint performance (two 30-s Wingate tests with 4-min recovery), muscle
efficiency and time-trial performance (TT, 5-min all-out) were assessed and biopsies from the m.
vastus lateralis and m. triceps brachii taken before and after training. VO2peak and Wmax increased
3–11% after training, with a more pronounced change in the arms (P < 0.05). Gross efficiency
improved for the arms (+8.8%, P < 0.05), but not the legs (−0.6%). Wingate peak and mean power
outputs improved similarly for the arms and legs, as did TT performance. After training, VO2 during
the two Wingate tests was increased by 52 and 6% for the arms and legs, respectively (P < 0.001).
In the case of the arms, VO2 was higher during the first than second Wingate test (64 vs. 44%, P <
0.05). During the TT, relative exercise intensity, HR, VO2, VCO2, VE, and Vt were all lower during
arm-cranking than leg-pedaling, and oxidation of fat was minimal, remaining so after training.
Despite the higher relative intensity, fat oxidation was 70% greater during leg-pedaling (P =
0.017). The aerobic energy contribution in the legs was larger than for the arms during the Wingate
tests, although VO2 for the arms was enhanced more by training, reducing the O2 deficit after SIT.
The levels of muscle glycogen, as well as the myosin heavy chain composition were unchanged in both
cases, while the activities of 3-hydroxyacyl-CoA-dehydrogenase and citrate synthase were elevated
only in the legs and capillarization enhanced in both limbs.
Multiple regression analysis demonstrated that the variables that predict TT performance
differ for the arms and legs. The primary mechanism of adaptation to SIT by both the arms and legs
is enhancement of aerobic energy production. However, with their higher
proportion of fast muscle fibers, the arms exhibit greater plasticity.
Description
Published version. Source at https://doi.org/10.3389/fphys.2016.00426