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Changes in neural drive to calf muscles during steady submaximal contractions after repeated static stretches
Author(s) -
Mazzo Melissa R.,
Weinman Logan E.,
Giustino Valerio,
Mclagan Bailey,
Maldonado John,
Enoka Roger M.
Publication year - 2021
Publication title -
the journal of physiology
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.802
H-Index - 240
eISSN - 1469-7793
pISSN - 0022-3751
DOI - 10.1113/jp281875
Subject(s) - isometric exercise , motor unit , motor unit recruitment , tendon , plantar flexion , electromyography , muscle contraction , anatomy , contraction (grammar) , physical medicine and rehabilitation , ankle , chemistry , medicine , physical therapy
Key points Repeated static‐stretching interventions consistently increase the range of motion about a joint and decrease total joint stiffness, but findings on the changes in muscle and connective‐tissue properties are mixed. The influence of these stretch‐induced changes on muscle function at submaximal forces is unknown. To address this gap in knowledge, the changes in neural drive to the plantar flexor muscles after a static‐stretch intervention were estimated. Neural drive to the plantar flexor muscles during a low‐force contraction increased after repeated static stretches. These findings suggest that adjustments in motor unit activity are necessary at low forces to accommodate reductions in the force‐generating and transmission capabilities of the muscle–tendon unit after repeated static stretches of the calf muscles.Abstract Static stretching decreases stiffness about a joint, but its influence on muscle–tendon unit function and muscle activation is unclear. We investigated the influence of three static stretches on changes in neural drive to the plantar flexor muscles, both after a stretch intervention and after a set of maximal voluntary contractions (MVCs). Estimates of neural drive were obtained during submaximal isometric contractions by decomposing high‐density electromyographic signals into the activity of individual motor units from medial gastrocnemius, lateral gastrocnemius and soleus. Motor units were matched across contractions and an estimate of neural drive to the plantar flexors was calculated by normalizing the cumulative spike train to the number of active motor units (normalized neural drive). Mean discharge rate increased after the stretch intervention during the 10% MVC task for all recorded motor units and those matched across conditions (all, P = 0.0046; matched only, P = 0.002), recruitment threshold decreased for motor units matched across contractions ( P = 0.022), and discharge rate at recruitment was elevated ( P = 0.004). Similarly, the estimate of normalized neural drive was significantly greater after the stretch intervention at 10% MVC torque ( P = 0.029), but not at 35% MVC torque. The adjustments in motor unit activity required to complete the 10% MVC task after stretch may have been partially attenuated by a set of plantar flexor MVCs. The increase in neural drive required to produce low plantar‐flexion torques after repeated static stretches of the calf muscles suggests stretch‐induced changes in muscle and connective tissue properties.