Research Centre for Musculoskeletal Science & Sports Medicine, Department of Life Sciences, Manchester Metropolitan University, Manchester, UK.
School of Mechanical, Aerospace and Civil Engineering, University of Manchester, Manchester, UK.
Gait Posture. 2020 Jun;79:229-233. doi: 10.1016/j.gaitpost.2020.03.011. Epub 2020 May 11.
Increased postural balance challenge is associated with more fluctuations in centre of pressure movement, indicating increased interference from the postural control system. The role of intrinsic foot muscles in balance control is relatively understudied and whether such control system interference occurs at the level of these muscles is unknown.
Do fewer fluctuations in intrinsic foot muscle excitation occur in response to increased postural balance challenge?
Surface EMGs were recorded using a grid of 13 × 5 channels from the plantar surface of the foot of 17 participants, who completed three balance tasks: bipedal stance; single leg stance and bipedal tip-toe. Centre of pressure (CoP) movement was calculated from simultaneously recorded force plate signals. Fluctuations in CoP and EMGs for each task were quantified using a sample entropy based metric, Entropy Halflife (EnHL). Longer EnHL indicates fewer signal fluctuations.
The shortest EMG EnHL, 9.27 ± 3.34 ms (median ± interquartile range), occurred during bipedal stance and the longest during bipedal tip-toe 15.46 ± 11.16 ms, with 18.80 ± 8.00 ms recorded for single leg stance. Differences were statistically significant between bipedal stance and both bipedal tip-toe (p < 0.001) and single leg stance (p < 0.001). CoP EnHL for both anterior-posterior and medial-lateral movements also differed significantly between tasks (p < 0.001, both cases). However, anterior-posterior CoP EnHL was longest for bipedal stance 259.84±230.22 ms and shortest for bipedal tip-toe 146.25±73.35 ms. Medial-lateral CoP EnHL was also longest during bipedal stance 215.73±187.58 ms, but shortest for single leg stance 113.48±83.01 ms.
Fewer fluctuations in intrinsic foot muscle excitation occur in response to increased postural balance challenge. Fluctuations in CoP movement during balance must be predominantly driven by excitation of muscles extrinsic to the foot. Intrinsic foot muscles therefore likely play a greater role in stabilisation of the foot than balance control during the postural tasks studied.
姿势平衡挑战的增加与中心压力移动的波动增加有关,这表明姿势控制系统的干扰增加。内在足部肌肉在平衡控制中的作用相对研究较少,并且这种控制系统干扰是否发生在这些肌肉的水平尚不清楚。
对增加的姿势平衡挑战的反应中,内在足部肌肉兴奋的波动是否减少?
使用 17 名参与者足底表面的 13×5 通道网格记录表面肌电图,他们完成了三项平衡任务:双足站立;单腿站立和双足踮脚尖。从同时记录的力板信号中计算中心压力(CoP)运动。使用基于样本熵的度量,熵半衰期(EnHL)量化每个任务的 CoP 和 EMG 波动。较长的 EnHL 表示信号波动较少。
最短的 EMG EnHL,9.27±3.34ms(中位数±四分位距),发生在双足站立时,最长的是双足踮脚尖 15.46±11.16ms,单腿站立时记录的为 18.80±8.00ms。双足站立与双足踮脚尖(p<0.001)和单腿站立(p<0.001)之间的差异具有统计学意义。前后和内外 CoP 的 EnHL 也在任务之间有显著差异(p<0.001,两种情况)。然而,双足站立时前后 CoP EnHL 最长 259.84±230.22ms,双足踮脚尖时最短 146.25±73.35ms。双足站立时内外 CoP EnHL 也最长 215.73±187.58ms,但单腿站立时最短 113.48±83.01ms。
对增加的姿势平衡挑战的反应中,内在足部肌肉兴奋的波动减少。平衡时 CoP 运动的波动必须主要由足部外在肌肉的兴奋驱动。因此,内在足部肌肉在研究的姿势任务中可能比平衡控制更能稳定足部。
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