蹬踏频率对递增式自行车运动时呼吸反应的影响。
Effects of pedal rate on respiratory responses to incremental bicycle work.
作者信息
Takano N
机构信息
Department of School Health, Faculty of Education, Kanazawa University, Japan.
出版信息
J Physiol. 1988 Feb;396:389-97. doi: 10.1113/jphysiol.1988.sp016968.
Abstract
- The influence of pedal rate on ventilatory response and breathing pattern during cycle exercise was studied in twelve untrained female subjects performing 15 W/min incremental work on a bicycle at 30 and 60 r.p.m. Comparisons were made within the range of aerobic work rate to avoid additional influences of a developing lactic acidosis. 2. At each pedal rate, CO2 excretion (VCO2) increased progressively to a level of 1.2 1/min with incrementally loaded cycling. With increasing VCO2, minute ventilation (VE), respiratory frequency (f), tidal volume (VT) and end-tidal PCO2 progressively increased. The inspiratory (TI) and expiratory (TE) durations decreased sharply on the transition from rest to unloaded cycling; further decreases occurred during incrementally loaded cycling. 3. Compared to 30 r.p.m., cycle exercise at 60 r.p.m. resulted in greater increases in VE and lower levels of end-tidal PCO2 at any given levels of VCO2. The greater ventilatory responses were due mostly to greater increases in f, which were in turn due to greater decreases in TE. The decrease in TI during cycling was little affected by changes in pedal rate. 4. The different magnitudes of ventilatory and PCO2 responses under the two pedal rate conditions suggest that neurogenic stimuli, central and/or peripheral in origin, participate in the control of exercise hyperpnoea in the non-steady-state phase. The possibility that the ventilatory response to cycle exercise is affected by the way that pedal rate is changed is discussed.
摘要
- 研究了12名未经训练的女性受试者在以30转/分钟和60转/分钟的转速在自行车上进行15瓦/分钟递增负荷运动时,踏频对通气反应和呼吸模式的影响。在有氧工作率范围内进行比较,以避免乳酸酸中毒发展带来的额外影响。2. 在每个踏频下,随着递增负荷骑行,二氧化碳排出量(VCO2)逐渐增加至1.2升/分钟的水平。随着VCO2增加,分钟通气量(VE)、呼吸频率(f)、潮气量(VT)和呼气末二氧化碳分压(PCO2)逐渐增加。从休息状态过渡到无负荷骑行时,吸气时间(TI)和呼气时间(TE)急剧缩短;在递增负荷骑行过程中进一步缩短。3. 与30转/分钟相比,在任何给定的VCO2水平下,60转/分钟的骑行运动导致VE增加幅度更大,呼气末PCO2水平更低。更大的通气反应主要归因于f的更大增加,而f的增加又归因于TE的更大缩短。骑行过程中TI的缩短受踏频变化的影响较小。4. 两种踏频条件下通气和PCO2反应的不同幅度表明,起源于中枢和/或外周的神经源性刺激参与了非稳态阶段运动性呼吸增强的控制。讨论了对骑行运动的通气反应受踏频改变方式影响的可能性。
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