Abstract
Behavioral evidence has suggested that a small number of muscle synergies may be responsible for activating a variety of muscles. Nevertheless, such dimensionality reduction may also be explained using the perspective of alternative hypotheses, such as predictions based on linear combinations of joint torques multiplied by corresponding coefficients. To compare the explanatory capacity of these hypotheses for describing muscle activation, we enrolled 12 male volunteers who performed isometric plantar flexor contractions at 10–100% of maximum effort. During each plantar flexor contraction, the knee extensor muscles were isometrically contracted at 0%, 50%, or 100% of maximum effort. Electromyographic activity was recorded from the vastus lateralis, medial gastrocnemius (MG), lateral gastrocnemius (LG), and soleus muscles and quantified using the average rectified value (ARV). At lower plantar flexion torque, regression analysis identified a clear linear relationship between the MG and soleus ARVs and between the MG and LG ARVs, suggesting the presence of muscle synergy (r2 > 0.65). The contraction of the knee extensor muscles induced a significant change in the slope of this relationship for both pairs of muscles (MG × soleus, P = 0.002; MG × LG, P = 0.006). Similarly, the slope of the linear relationship between the plantar flexion torque and the ARV of the MG or soleus changed significantly with knee extensor contraction (P = 0.031 and P = 0.041, respectively). These results suggest that muscle synergies characterized by non-mechanical constraints are selectively recruited according to whether contraction of the knee extensor muscles is performed simultaneously, which is relatively consistent with the muscle synergy hypothesis.
Highlights
The human musculoskeletal system comprises approximately 400 skeletal muscles [1] that provide flexible solutions to various complex movements
vastus lateralis (VL) average rectified value (ARV) was lower than the target level, there was a significant main effect of knee extensor contraction on VL ARV at both lower plantar flexion torque (F2,22 = 614.7, ε = 0.744, P < 0.001) and higher plantar flexion torque (F2,22 = 874.4, ε = 0.816, P < 0.001)
Post hoc tests revealed a significant increase in VL ARV from 0% to 50% knee extensor MVC trials (KEMVC), from 0% to 100% KEMVC, and from 50% to 100% KEMVC at both lower and higher plantar flexion torque (P < 0.001, for each comparison)
Summary
The human musculoskeletal system comprises approximately 400 skeletal muscles [1] that provide flexible solutions to various complex movements. Such analysis is unable to extract linear relationships from complicated activation patterns in which a single muscle can participate in multiple muscle synergies To model these more complex situations, computational decomposition techniques such as non-negative matrix factorization have recently been applied for the identification of multiple linear relationships in muscle activities across different tasks [13,14,15,16]. These techniques have demonstrated that various movements can be described by a linear combination of a relatively small number of muscle synergies
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