行走过程中足部内在肌与外在肌的协调作用。

Coordination of intrinsic and extrinsic foot muscles during walking.

作者信息

Zelik Karl E, La Scaleia Valentina, Ivanenko Yuri P, Lacquaniti Francesco

机构信息

Laboratory of Neuromotor Physiology, IRCCS Santa Lucia Foundation, Via Ardeatina 306, 00179, Rome, Italy,

出版信息

Eur J Appl Physiol. 2015 Apr;115(4):691-701. doi: 10.1007/s00421-014-3056-x. Epub 2014 Nov 25.

DOI:10.1007/s00421-014-3056-x

PMID:25420444

Abstract

PURPOSE

The human foot undergoes complex deformations during walking due to passive tissues and active muscles. However, based on prior recordings it is unclear if muscles that contribute to flexion/extension of the metatarsophalangeal (MTP) joints are activated synchronously to modulate joint impedance, or sequentially to perform distinct biomechanical functions. We investigated the coordination of MTP flexors and extensors with respect to each other, and to other ankle-foot muscles.

METHODS

We analyzed surface electromyographic (EMG) recordings of intrinsic and extrinsic foot muscles for healthy individuals during level treadmill walking, and also during sideways and tiptoe gaits. We computed stride-averaged EMG envelopes and used the timing of peak muscle activity to assess synchronous vs. sequential coordination.

RESULTS

We found that peak MTP flexor activity occurred significantly before peak MTP extensor activity during walking (P < 0.001). The period around stance-to-swing transition could be roughly characterized by sequential peak muscle activity from the ankle plantarflexors, MTP flexors, MTP extensors, and then ankle dorsiflexors. We found that foot muscles that activated synchronously during forward walking tended to dissociate during other locomotor tasks. For instance, extensor hallucis brevis and extensor digitorum brevis muscle activation peaks decoupled during sideways gait.

CONCLUSIONS

The sequential peak activity of MTP flexors followed by MTP extensors suggests that their biomechanical contributions may be largely separable from each other and from other extrinsic foot muscles during walking. Meanwhile, the task-specific coordination of the foot muscles during other modes of locomotion indicates a high-level of specificity in their function and control.

摘要

目的

由于被动组织和主动肌肉的作用，人类足部在行走过程中会经历复杂的变形。然而，根据之前的记录，尚不清楚对跖趾（MTP）关节屈伸有贡献的肌肉是同步激活以调节关节阻抗，还是顺序激活以执行不同的生物力学功能。我们研究了MTP屈肌和伸肌之间以及它们与其他踝足部肌肉之间的协调性。

方法

我们分析了健康个体在水平跑步机行走、侧行和踮步行走过程中足部内在和外在肌肉的表面肌电图（EMG）记录。我们计算了步幅平均EMG包络，并使用肌肉活动峰值的时间来评估同步与顺序协调。

结果

我们发现，在行走过程中，MTP屈肌的活动峰值显著早于MTP伸肌的活动峰值（P < 0.001）。从站立到摆动过渡的时间段大致可由踝跖屈肌、MTP屈肌、MTP伸肌，然后是踝背屈肌的顺序峰值肌肉活动来表征。我们发现，在向前行走过程中同步激活的足部肌肉在其他运动任务中往往会分离。例如，在侧行步态中，拇短伸肌和趾短伸肌的激活峰值解耦。

结论

MTP屈肌先于MTP伸肌出现顺序峰值活动，这表明在行走过程中，它们的生物力学贡献可能在很大程度上彼此分离，并且与其他足部外在肌肉的贡献也相互分离。同时，在其他运动模式下足部肌肉的特定任务协调表明它们在功能和控制方面具有高度特异性。

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行走过程中足部内在肌与外在肌的协调作用。

Coordination of intrinsic and extrinsic foot muscles during walking.

作者信息

机构信息

出版信息

PURPOSE

METHODS

RESULTS

CONCLUSIONS

目的

方法

结果

结论

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