Zinner Christoph, Hauser Anna, Born Dennis-Peter, Wehrlin Jon P, Holmberg Hans-Christer, Sperlich Billy
Department of Sport Science, Julius-Maximilians-University Würzburg, Würzburg, Germany; Swedish Winter Sports Research Centre, Department of Health Sciences, Mid Sweden University, Östersund, Sweden.
Swiss Federal Institute of Sport, Section for Elite Sport, Magglingen, Switzerland.
PLoS One. 2015 Oct 15;10(10):e0140616. doi: 10.1371/journal.pone.0140616. eCollection 2015.
Here, we evaluated the influence of breathing oxygen at different partial pressures during recovery from exercise on performance at sea-level and a simulated altitude of 1800 m, as reflected in activation of different upper body muscles, and oxygenation of the m. triceps brachii. Ten well-trained, male endurance athletes (25.3±4.1 yrs; 179.2±4.5 cm; 74.2±3.4 kg) performed four test trials, each involving three 3-min sessions on a double-poling ergometer with 3-min intervals of recovery. One trial was conducted entirely under normoxic (No) and another under hypoxic conditions (Ho; FiO2 = 0.165). In the third and fourth trials, the exercise was performed in normoxia and hypoxia, respectively, with hyperoxic recovery (HOX; FiO2 = 1.00) in both cases. Arterial hemoglobin saturation was higher under the two HOX conditions than without HOX (p<0.05). Integrated muscle electrical activity was not influenced by the oxygen content (best d = 0.51). Furthermore, the only difference in tissue saturation index measured via near-infrared spectroscopy observed was between the recovery periods during the NoNo and HoHOX interventions (P<0.05, d = 0.93). In the case of HoHo the athletes' Pmean declined from the first to the third interval (P < 0.05), whereas Pmean was unaltered under the HoHOX, NoHOX and NoNo conditions. We conclude that the less pronounced decline in Pmean during 3 x 3-min double-poling sprints in normoxia and hypoxia with hyperoxic recovery is not related to changes in muscle activity or oxygenation. Moreover, we conclude that hyperoxia (FiO2 = 1.00) used in conjunction with hypoxic or normoxic work intervals may serve as an effective aid when inhaled during the subsequent recovery intervals.
在此,我们评估了运动恢复期间呼吸不同分压氧气对海平面及模拟海拔1800米高度运动表现的影响,这体现在不同上肢肌肉的激活以及肱三头肌的氧合情况上。十名训练有素的男性耐力运动员(25.3±4.1岁;179.2±4.5厘米;74.2±3.4千克)进行了四项测试试验,每项试验包括在双杆测力计上进行三个3分钟的时段,中间间隔3分钟恢复时间。一项试验完全在常氧(No)条件下进行,另一项在低氧条件下(Ho;吸入氧分数=0.165)进行。在第三和第四项试验中,运动分别在常氧和低氧条件下进行,两种情况下恢复期间均进行高氧恢复(HOX;吸入氧分数=1.00)。两种HOX条件下的动脉血红蛋白饱和度均高于无HOX时(p<0.05)。肌肉综合电活动不受氧含量影响(最佳效应量d=0.51)。此外,通过近红外光谱法测量的组织饱和度指数唯一观察到的差异存在于NoNo和HoHOX干预的恢复期间(P<0.05,效应量d=0.93)。在HoHo情况下,运动员的平均肺动脉压从第一个时段到第三个时段下降(P<0.05),而在HoHOX、NoHOX和NoNo条件下平均肺动脉压未改变。我们得出结论,在常氧和低氧条件下进行3×3分钟双杆冲刺且恢复期间进行高氧恢复时,平均肺动脉压下降不明显与肌肉活动或氧合变化无关。此外,我们得出结论,在低氧或常氧工作时段后恢复期间吸入的高氧(吸入氧分数=1.00)可能是一种有效的辅助手段。