The synchronization of muscle activity and body segment movements during a running cycle.

Medicine and science in sports Pub Date : 1979-01-01 DOI:10.1249/00005768-197901140-00002

Elliott Bc, Blanksby Ba

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引用次数: 47

Abstract

: Locomotor patterns of running were studied using computerization to synchronize electromyography (EMG) and cinematography (CMG). Surface electrodes monitored the muscle action potentials from rectus femoris, vastus lateralis, vastus medialis, biceps femoris, semitendinosus, semimembranosus, triceps surae and tibialis anterior muscles as 10 female subjects ran on a treadmill at speeds of 2.5 m/s and 3.5 m/s. Averaged integrated electromyograms were formulated to represent action potential levels for various sub-sections of the running cycle. Beginning at foot contact, the running cycle was dominated initially by muscle activity concerned with stabilization. The co-contraction of vastus medialis, vastus lateralis, semimembranosus, tibialis anterior, biceps femoris and triceps surae were associated with clockwise rotation (running from left to right) of the thigh, leg and foot in providing a stable base during the early support phase. Lower limb stabilization then gave way to the powerful driving thrust of the mid and late support phases. This period was characterized by increases in the activity levels from triceps surae and biceps femoris. The co-ordination of inertial effects and secondary muscular activity was associated with leg flexion as the thigh changed direction and with leg extension during the swing phase of running. This conclusion was supported by both EMG and resultant muscle moment of force date. Increased activity from semimembranosus and semitendinosus occurred with cessation of thigh flexion and leg extension prior to the subsequent heel strike. Tibialis anterior also eccentrically contracted to place the foot on the treadmill under control. The increase in the running speed was related to an increase in muscle action potential (in parts of the cycle) where the particular muscle was functional. This increase was paralleled kinetically by an increase in the resultant muscle moment of force level.

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在一个跑步周期中肌肉活动和身体部分运动的同步。

用计算机同步肌电图(EMG)和电影摄影(CMG)研究跑步运动模式。当10名女性受试者在跑步机上以2.5 m/s和3.5 m/s的速度跑步时，表面电极监测股直肌、股外侧肌、股内侧肌、股二头肌、半腱肌、半膜肌、三头肌和胫前肌的肌肉动作电位。用平均综合肌电图表示跑步周期各阶段的动作电位水平。从脚部接触开始，跑步周期最初由与稳定有关的肌肉活动主导。股内侧肌、股外侧肌、半膜肌、胫骨前肌、股二头肌和面三头肌的共同收缩与大腿、腿和足的顺时针旋转(从左到右)有关，在早期支撑阶段提供稳定的基础。随后，下肢稳定让位给中期和后期支撑阶段的强大驱动推力。这一时期的特点是肱三头肌和股二头肌的活动水平增加。惯性效应和次级肌肉活动的协调与大腿改变方向时的腿屈和跑步摇摆阶段的腿伸有关。这一结论得到了肌电图和所得肌力矩数据的支持。半膜肌和半腱肌的活动增加发生在大腿屈曲和腿伸展停止之前，随后的脚跟撞击。胫骨前肌也偏心收缩，使脚在跑步机上受到控制。跑步速度的增加与肌肉动作电位的增加有关(在循环的一部分)，在那里特定的肌肉是功能性的。这种增加与由此产生的肌肉力矩水平的增加在动力学上是平行的。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Medicine and science in sports

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