Training History-Dependent Functional Role of EMG Model-Predicted Antagonist Moments in Knee Extensor Moment Generation in Healthy Young Adults

Biomechanics (Basel, Switzerland) Pub Date : 2022-01-06 DOI:10.3390/biomechanics2010002

T. Hortobágyi, P. Devita, Robert B E Brady, P. Rider

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Abstract

Resistance training (RT) improves the skeletal muscle’s ability to generate maximal voluntary force and is accompanied by changes in the activation of the antagonist muscle which is not targeted primarily by RT. However, the nature and role of neural adaptation to RT in the antagonist muscle is paradoxical and not well understood. We compared moments, agonist muscle activation, antagonist activation, agonist-antagonist coactivation, and electromyographic (EMG) model-predicted moments generated by antagonist hamstring muscle coactivation during isokinetic knee extension in leg strength-trained (n = 10) and untrained (n = 11) healthy, younger adults. Trained vs. untrained adults were up to 58% stronger. During knee extension, hamstring activation was 1.6-fold greater in trained vs. untrained adults (p = 0.022). This hamstring activation produced 2.6-fold greater model-predicted antagonist moments during knee extension in the trained (42.7 ± 19.55 Nm) vs. untrained group (16.4 ± 12.18 Nm; p = 0.004), which counteracted (reduced) quadriceps knee extensor moments ~43 Nm (0.54 Nm·kg−1) and by ~16 Nm (0.25 Nm·kg−1) in trained vs. untrained. Antagonist hamstring coactivation correlated with decreases and increases, respectively, in quadriceps moments in trained and untrained. The EMG model-predicted antagonist moments revealed training history-dependent functional roles in knee extensor moment generation.

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肌电模型预测的拮抗力矩在健康年轻人膝伸肌力矩生成中的训练历史相关功能作用

阻力训练(RT)提高骨骼肌产生最大自主力的能力，并伴随着拮抗肌激活的变化，这不是RT的主要目标。然而，拮抗肌对RT的神经适应的性质和作用是矛盾的，并且尚未得到很好的理解。我们比较了在腿部力量训练(n = 10)和未训练(n = 11)的健康年轻人中，在等速膝关节伸展过程中，激动剂肌肉激活、拮抗剂激活、激动剂-拮抗剂协同激活和肌电图(EMG)模型预测的拮抗剂腘绳肌协同激活产生的力矩。受过训练的成年人比未受过训练的成年人强壮58%。在膝关节伸展时，经过训练的成年人的腘绳肌激活比未经训练的成人高1.6倍(p = 0.022)。训练组(42.7±19.55 Nm)与未训练组(16.4±12.18 Nm)相比，腿筋激活在膝关节伸展时产生2.6倍的模型预测拮抗剂力矩(42.7±19.55 Nm);p = 0.004)，这抵消(减少)股四头肌膝关节伸肌力矩~43 Nm (0.54 Nm·kg - 1)和~16 Nm (0.25 Nm·kg - 1)。拮抗剂腿筋共激活分别与训练和未训练时股四头肌力矩的减少和增加相关。肌电模型预测的拮抗剂力矩揭示了训练历史依赖的膝关节伸肌力矩产生的功能作用。

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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来源期刊

Biomechanics (Basel, Switzerland)

CiteScore

1.50

自引率

0.00%

发文量