Langsetmo I, Weigle G E, Fedde M R, Erickson H H, Barstow T J, Poole D C
Departments of Anatomy and Physiology and Kinesiology, Kansas State University, Manhattan, Kansas 66506-5602, USA.
J Appl Physiol (1985). 1997 Oct;83(4):1235-41. doi: 10.1152/jappl.1997.83.4.1235.
The horse is a superb athlete, achieving a maximal O2 uptake (approximately 160 ml . min-1 . kg-1) approaching twice that of the fittest humans. Although equine O2 uptake (VO2) kinetics are reportedly fast, they have not been precisely characterized, nor has their exercise intensity dependence been elucidated. To address these issues, adult male horses underwent incremental treadmill testing to determine their lactate threshold (Tlac) and peak VO2 (VO2 peak), and kinetic features of their VO2 response to "square-wave" work forcings were resolved using exercise transitions from 3 m/s to a below-Tlac speed of 7 m/s or an above-Tlac speed of 12.3 +/- 0.7 m/s (i.e., between Tlac and VO2 peak) sustained for 6 min. VO2 and CO2 output were measured using an open-flow system: pulmonary artery temperature was monitored, and mixed venous blood was sampled for plasma lactate. VO2 kinetics at work levels below Tlac were well fit by a two-phase exponential model, with a phase 2 time constant (tau1 = 10.0 +/- 0.9 s) that followed a time delay (TD1 = 18.9 +/- 1.9 s). TD1 was similar to that found in humans performing leg cycling exercise, but the time constant was substantially faster. For speeds above Tlac, TD1 was unchanged (20.3 +/- 1.2 s); however, the phase 2 time constant was significantly slower (tau1 = 20.7 +/- 3.4 s, P < 0.05) than for exercise below Tlac. Furthermore, in four of five horses, a secondary, delayed increase in VO2 became evident 135.7 +/- 28.5 s after the exercise transition. This "slow component" accounted for approximately 12% (5.8 +/- 2.7 l/min) of the net increase in exercise VO2. We conclude that, at exercise intensities below and above Tlac, qualitative features of VO2 kinetics in the horse are similar to those in humans. However, at speeds below Tlac the fast component of the response is more rapid than that reported for humans, likely reflecting different energetics of O2 utilization within equine muscle fibers.
马是超级运动员,其最大摄氧量(约160毫升·分钟⁻¹·千克⁻¹)接近最健康人类的两倍。尽管据报道马的摄氧量(VO₂)动力学很快,但尚未得到精确描述,其对运动强度的依赖性也未阐明。为解决这些问题,成年雄性马进行了递增式跑步机测试,以确定其乳酸阈值(Tlac)和峰值VO₂(VO₂峰值),并通过从3米/秒到低于Tlac速度7米/秒或高于Tlac速度12.3±0.7米/秒(即介于Tlac和VO₂峰值之间)的运动转换持续6分钟,来解析其VO₂对“方波”负荷响应的动力学特征。使用开放流系统测量VO₂和二氧化碳输出:监测肺动脉温度,并采集混合静脉血以测定血浆乳酸。低于Tlac工作水平时的VO₂动力学通过双相指数模型拟合良好,第二阶段时间常数(tau1 = 10.0±0.9秒)伴有时间延迟(TD1 = 18.9±1.9秒)。TD1与进行腿部自行车运动的人类相似,但时间常数明显更快。对于高于Tlac的速度,TD1不变(20.3±1.2秒);然而,第二阶段时间常数明显慢于低于Tlac的运动(tau1 = 20.7±3.4秒,P < 0.05)。此外,在五匹马中的四匹中,运动转换后135.7±28.5秒出现了VO₂的二次延迟增加。这种“慢成分”约占运动VO₂净增加量的12%(5.8±2.7升/分钟)。我们得出结论,在低于和高于Tlac的运动强度下,马的VO₂动力学定性特征与人类相似。然而,在低于Tlac的速度下,响应的快速成分比人类报道的更快,这可能反映了马肌纤维内氧气利用的不同能量学特征。
