Corticospinal excitability remains unchanged in the presence of residual force enhancement and does not contribute to increased torque production

It is unclear whether cortical and spinal excitability modulations contribute to enhanced SSC performance. Therefore, this study investigated cortical and spinal excitability modulations during and following shortening of stretch-shortening cycle (SSC) contractions compared with pure shortening (SHO) contractions. Participants (N = 18) performed submaximal voluntary plantar flexion contractions while prone on the dynamometer bench. The right foot was strapped onto the dynamometer footplate attachment and the resultant ankle joint torque and crank arm angle were recorded. Cortical and spinal excitability modulations of the soleus muscle were analyzed by eliciting compound muscle actional potentials via electrical nerve stimulation, cervicomedullary motor-evoked potentials (CMEPs) via electrical stimulation of the spinal cord, and motor-evoked potentials (MEPs) via magnetic stimulation of the motor cortex. Mean torque following stretch was significantly increased by 7 plus minus 3% (p=0.029) compared with the fixed-end reference (REF) contraction and mean torque during shortening of SSC compared with SHO was significantly increased by 12 plus minus 24% (p=0.046). Mean steady-state torque was significantly lower by 13 plus minus 3% (p=0.006) and 9 plus minus 12% (p=0.011) following SSC compared with REF and SHO, respectively. Mean steady-state torque was not significantly lower following SHO compared with REF (7 plus minus 8%, p=0.456). CMEPs and MEPs were also not significantly different during shortening of SSC compared with SHO or during the steady state of SSC, SHO, and REF. Therefore, our results indicate that SSC performance was not associated with cortical or spinal excitability modulations during or after shortening, but rather driven by mechanical mechanisms triggered during active stretch.

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Corticospinal excitability remains unchanged in the presence of residual force enhancement and does not contribute to increased torque production

Cited by 2 publications

References 41 publications

The history-dependent features of muscle force production: A challenge to the cross-bridge theory and their functional implications

The history-dependent features of muscle force production: A challenge to the cross-bridge theory and their functional implications

The stretch-shortening cycle effect is not associated with cortical or spinal excitability modulations

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