CNRS, ISM UMR 7287, Aix-Marseille Université, Marseille, France.
ToNIC, Toulouse NeuroImaging Center, INSERM, UPS, Université de Toulouse, Toulouse, France.
Eur J Appl Physiol. 2017 Nov;117(11):2309-2320. doi: 10.1007/s00421-017-3718-6. Epub 2017 Sep 20.
The mechanisms governing the control of musculoskeletal redundancy remain to be fully understood. The hand is highly redundant, and shows different functional role of extensors according to its configuration for a same functional task of finger flexion. Through intermuscular coherence analysis combined with hand musculoskeletal modelling during maximal isometric hand contractions, our aim was to better understand the neural mechanisms underlying the control of muscle force coordination and agonist-antagonist co-contraction.
Thirteen participants performed maximal isometric flexions of the fingers in two configurations: power grip (Power) and finger-pressing on a surface (Press). Hand kinematics and force/moment measurements were used as inputs in a musculoskeletal model of the hand to determine muscular tensions and co-contraction. EMG-EMG coherence analysis was performed between wrist and finger flexors and extensor muscle pairs in alpha, beta and gamma frequency bands.
Concomitantly with tailored muscle force coordination and increased co-contraction between Press and Power (mean difference: 48.08%; p < 0.05), our results showed muscle-pair-specific modulation of intermuscular coupling, characterized by pair-specific modulation of EMG-EMG coherence between Power and Press (p < 0.05), and a negative linear association between co-contraction and intermuscular coupling for the ECR/FCR agonist-antagonist muscle pair (r = - 0.65; p < 0.05).
This study brings new evidence that pair-specific modulation of EMG-EMG coherence is related to modulation of muscle force coordination during hand contractions. Our results highlight the functional importance of intermuscular coupling as a mechanism contributing to the control of muscle force synergies and agonist-antagonist co-contraction.
控制肌肉骨骼冗余的机制仍有待充分理解。手具有高度的冗余性,并且根据其用于相同手指弯曲功能任务的配置,表现出不同的伸肌功能作用。通过在最大等长手部收缩期间结合肌肉间相干性分析和手部骨骼肌肉建模,我们旨在更好地理解控制肌肉力量协调和拮抗肌共同收缩的神经机制。
13 名参与者以两种配置进行最大等距手指弯曲:力握(Power)和手指按压表面(Press)。手部运动学和力/力矩测量值被用作手部骨骼肌肉模型的输入,以确定肌肉张力和共同收缩。在 alpha、beta 和 gamma 频带中,在腕部和手指屈肌和伸肌肌肉对之间进行肌电图-肌电图相干性分析。
与定制的肌肉力量协调和 Press 与 Power 之间增加的共同收缩(平均差异:48.08%;p<0.05)同时,我们的结果显示肌肉对特异性调制的肌肉间耦合,其特征是 Power 和 Press 之间肌电图-肌电图相干性的对特异性调制(p<0.05),以及拮抗肌对 ECR/FCR 的共同收缩与肌肉间耦合之间的负线性关联(r=-0.65;p<0.05)。
这项研究提供了新的证据,表明肌电图-肌电图相干性的对特异性调制与手部收缩期间肌肉力量协调的调制有关。我们的结果强调了肌肉间耦合作为一种机制的功能重要性,该机制有助于控制肌肉力量协同作用和拮抗肌共同收缩。
