男性短跑训练后进行剧烈运动时肺部和活跃骨骼肌气体交换增强。
Enhanced pulmonary and active skeletal muscle gas exchange during intense exercise after sprint training in men.
作者信息
McKenna M J, Heigenhauser G J, McKelvie R S, Obminski G, MacDougall J D, Jones N L
机构信息
Department of Medicine, McMaster University, Hamilton, Ontario, Canada.
出版信息
J Physiol. 1997 Jun 15;501 ( Pt 3)(Pt 3):703-16. doi: 10.1111/j.1469-7793.1997.703bm.x.
Abstract
- This study investigated the effects of 7 weeks of sprint training on gas exchange across the lungs and active skeletal muscle during and following maximal cycling exercise in eight healthy males. 2. Pulmonary oxygen uptake (VO2) and carbon dioxide output (VCO2) were measured before and after training during incremental exercise (n = 8) and during and in recovery from a maximal 30 s sprint exercise bout by breath-by-breath analysis (n = 6). To determine gas exchange by the exercising leg muscles, brachial arterial and femoral venous blood O2 and CO2 contents and lactate concentration were measured at rest, during the final 10 s of exercise and during 10 min of recovery. 3. Training increased (P < 0.05) the maximal incremental exercise values of ventilation (VE, by 15.7 +/- 7.1%), VCO2 (by 9.3 +/- 2.1%) and VO2 (by 15.0 +/- 4.2%). Sprint exercise peak power (3.9 +/- 1.0% increase) and cumulative 30 s work (11.7 +/- 2.8% increase) were increased and fatigue index was reduced (by -9.2 +/- 1.5%) after training (P < 0.05). The highest VE, VCO2 and VO2 values attained during sprint exercise were not significantly changed after training, but a significant (P < 0.05) training effect indicated increased VE (by 19.2 +/- 7.9%), VCO2 (by 9.3 +/- 2.1%) and VO2 (by 12.7 +/- 6.5%), primarily reflecting elevated post-exercise values after training. 4. Arterial O2 and CO2 contents were lower after training, by respective mean differences of 3.4 and 21.9 ml l-1 (P < 0.05), whereas the arteriovenous O2 and CO2 content differences and the respiratory exchange ratio across the leg were unchanged by training. 5. Arterial whole blood lactate concentration and the net lactate release by exercising muscle were unchanged by training. 6. The greater peak pulmonary VO2 and VCO2 with sprint exercise, the increased maximal incremental values, unchanged arterial blood lactate concentration and greater sprint performance all point strongly towards enhanced gas exchange across the lungs and in active muscles after sprint training. Enhanced aerobic metabolism after sprint training may contribute to reduced fatigability during maximal exercise, whilst greater pulmonary CO2 output may improve acid-base control after training.
摘要
- 本研究调查了8名健康男性进行7周短跑训练对最大强度骑行运动期间及之后肺和活跃骨骼肌气体交换的影响。2. 通过逐次呼吸分析,在递增运动期间(n = 8)以及在30秒最大强度短跑运动期间和恢复过程中,测量训练前后的肺氧摄取量(VO2)和二氧化碳排出量(VCO2)(n = 6)。为了确定运动腿部肌肉的气体交换情况,在静息状态、运动最后10秒以及恢复10分钟期间,测量肱动脉和股静脉血中的氧和二氧化碳含量以及乳酸浓度。3. 训练使递增运动时的最大通气量(VE,增加15.7±7.1%)、VCO2(增加9.3±2.1%)和VO2(增加15.0±4.2%)显著增加(P < 0.05)。训练后,短跑运动的峰值功率增加(3.9±1.0%),累积30秒功增加(11.7±2.8%),疲劳指数降低(-9.2±1.5%)(P < 0.05)。训练后,短跑运动期间达到的最高VE、VCO2和VO2值无显著变化,但显著的训练效果(P < 0.05)表明VE增加(19.2±7.9%)、VCO2增加(9.3±2.1%)和VO2增加(12.7±6.5%),主要反映训练后运动后值升高。4. 训练后动脉血氧和二氧化碳含量降低,平均差异分别为3.4和21.9 ml l-1(P < 0.05),而腿部动静脉氧和二氧化碳含量差异以及呼吸交换率不受训练影响。5. 训练后动脉全血乳酸浓度和运动肌肉的净乳酸释放量无变化。6. 短跑运动时更大的肺VO2和VCO2峰值、增加的最大递增运动值、不变的动脉血乳酸浓度以及更好短跑表现均有力表明,短跑训练后肺和活跃肌肉的气体交换增强。短跑训练后增强的有氧代谢可能有助于在最大运动期间降低疲劳性,而更大的肺二氧化碳排出量可能改善训练后的酸碱平衡。
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