Askew Graham N, Marsh Richard L
School of Biology, University of Leeds, Leeds LS2 9JT, UK.
J Exp Biol. 2002 Aug;205(Pt 15):2153-60. doi: 10.1242/jeb.205.15.2153.
Take-off in birds at high speeds and steep angles of elevation requires a high burst power output. The mean power output of the pectoralis muscle of blue-breasted quail (Coturnix chinensis) during take-off is approximately 400 W kg(-1) muscle, as determined using two independent methods. This burst power output is much higher than has been measured in any other cyclically contracting muscle. The power output of muscle is determined by the interactions between the physiological properties of the muscle, the stimulation regime imposed by the central nervous system and the details of the strain cycle, which are determined by the reciprocal interaction between the muscle properties and the environmental load. The physiological adaptations that enable a high power output to be achieved are those that allow the muscle to develop high stresses whilst shortening rapidly. These characteristics include a high myofibrillar density, rapid twitch contraction kinetics and a high maximum intrinsic velocity of shortening. In addition, several features of the strain cycle increase the power output of the quail pectoralis muscle. First, the muscle operates at a mean length shorter than the plateau of the length/force relationship. Second, the muscle length trajectory is asymmetrical, with 70 % of the cycle spent shortening. The asymmetrical cycle is expected to increase the power output substantially. Third, subtle deviations in the velocity profile improve power output compared with a simple asymmetrical cycle with constant lengthening and shortening rates. The high burst power outputs found in the flight muscles of quail and similar birds are limited to very brief efforts before fatigue occurs. This strong but short flight performance is well-suited to the rapid-response anti-predation strategy of these birds that involves a short flight coupled with a subsequent sustained escape by running. These considerations serve as a reminder that the maximum power-producing capacities of muscles need to be considered in the context of the in vivo situation within which the muscles operate.
鸟类高速且以陡峭仰角起飞需要强大的爆发功率输出。通过两种独立方法测定,蓝胸鹑(Coturnix chinensis)起飞时胸肌的平均功率输出约为400 W kg⁻¹肌肉。这种爆发功率输出远高于在任何其他周期性收缩肌肉中测得的数值。肌肉的功率输出由肌肉生理特性、中枢神经系统施加的刺激模式以及应变周期细节之间的相互作用决定,而应变周期细节由肌肉特性与环境负荷之间的相互作用决定。能够实现高功率输出的生理适应性变化是那些能使肌肉在快速缩短的同时产生高应力的变化。这些特性包括高肌原纤维密度、快速抽搐收缩动力学以及高最大固有缩短速度。此外,应变周期的几个特征增加了鹌鹑胸肌的功率输出。首先,肌肉在平均长度短于长度/力关系平台期的情况下工作。其次,肌肉长度轨迹不对称,70%的周期用于缩短。预计这种不对称周期会大幅增加功率输出。第三,与具有恒定伸长和缩短速率的简单不对称周期相比,速度曲线中的细微偏差提高了功率输出。在鹌鹑及类似鸟类的飞行肌肉中发现的高爆发功率输出仅限于疲劳发生前的非常短暂的用力。这种强大但短暂的飞行性能非常适合这些鸟类的快速反应抗捕食策略,该策略包括短距离飞行并随后通过奔跑持续逃脱。这些考虑提醒我们,需要在肌肉运作的体内环境背景下考虑肌肉的最大功率产生能力。
