Prilutsky B I, Herzog W, Allinger T L
Human Performance Laboratory, University of Calgary, Alberta, Canada.
J Exp Biol. 1996 Apr;199(Pt 4):801-14. doi: 10.1242/jeb.199.4.801.
Electrical activity, forces, power and work of the soleus (SO), the gastrocnemius (GA) and the plantaris (PL) muscles were measured during locomotion in the cat in order to study the functional role of these ankle extensor muscles. Forces and electrical activity (EMG) of the three muscles were measured using home-made force transducers and bipolar, indwelling wire electrodes, respectively, for walking and trotting at speeds of 0.4 to 1.8 m s-1 on a motor-driven treadmill. Video records and a geometrical model of the cat hindlimb were used for calculating the rates of change in lengths of the SO, GA and PL muscles. The instantaneous maximum possible force that can be produced by a muscle at a given fibre length and the rate of change in fibre length (termed contractile abilities) were estimated for each muscle throughout the step cycle. Fibre lengths of the SO, GA and PL were calculated using a planar, geometrical muscle model, measured muscle forces and kinematics, and morphological measurements from the animal after it had been killed. Mechanical power and work of SO, GA and PL were calculated for 144 step cycles. The contribution of the positive work done by the ankle extensor muscles of one hindlimb to the increase of the total mechanical energy of the body (estimated from values in the literature) increased from 4-11% at speeds of locomotion of 0.4 and 0.8 m s-1 to 7-16% at speeds of 1.2 m s-1 and above. The relative contributions of the negative and positive work to the total negative and positive work done by the three ankle extensor muscles increased for GA, decreased for SO and remained about the same for PL, with increasing speeds of locomotion. At speeds of 0.4-0.8 m s-1, the positive work normalized to muscle mass was 7.5-11.0 J kg-1, 1.9-3.0 J kg-1 and 5.3-8.4 J kg-1 for SO, GA and PL, respectively. At speeds of 1.2-1.8 m s-1, the corresponding values were 9.8-16.7 J kg-1, 6.0-10.7 J kg-1 and 13.4-25.0 J kg-1. Peak forces of GA and PL increased and peak forces of SO did not change substantially with increasing speeds of locomotion. The time of decrease of force and the time of decrease of power after peak values had been achieved were much shorter for SO than the corresponding times for GA and PL at fast speeds of locomotion. The faster decrease in the force and power of SO compared with GA and PL was caused by the fast decrease of the contractile abilities and the activation of SO. The results of this study suggest that the ankle extensor muscles play a significant role in the generation of mechanical energy for locomotion.
为了研究比目鱼肌(SO)、腓肠肌(GA)和跖肌(PL)这些踝关节伸肌的功能作用,在猫运动过程中对其电活动、力、功率和功进行了测量。在电动跑步机上,分别使用自制的力传感器和双极植入式线电极,以0.4至1.8米/秒的速度对这三块肌肉进行行走和小跑时的力和电活动(肌电图)测量。利用猫后肢的视频记录和几何模型来计算SO、GA和PL肌肉长度的变化率。在整个步周期内,对每块肌肉估计了在给定纤维长度下肌肉能够产生的瞬时最大可能力以及纤维长度的变化率(称为收缩能力)。使用平面几何肌肉模型、测量的肌肉力和运动学以及动物处死后的形态学测量数据来计算SO、GA和PL的纤维长度。计算了144个步周期内SO、GA和PL的机械功率和功。一条后肢的踝关节伸肌所做的正功对身体总机械能增加的贡献(根据文献中的值估算),在0.4和0.8米/秒的运动速度下从4 - 11%增加到1.2米/秒及以上速度时的7 - 16%。随着运动速度增加,GA的负功和正功对三块踝关节伸肌所做总负功和总正功的相对贡献增加,SO的相对贡献减少,PL的相对贡献基本保持不变。在0.4 - 0.8米/秒的速度下,SO、GA和PL归一化至肌肉质量的正功分别为7.5 - 11.0焦耳/千克、1.9 - 3.0焦耳/千克和5.3 - 8.4焦耳/千克。在1.2 - 1.8米/秒的速度下,相应的值分别为9.8 - 16.7焦耳/千克、6.0 - 10.7焦耳/千克和13.
