Abstract
Neuromuscular electrical stimulation (NMES) is often delivered at frequencies that recruit motor units (MUs) at unphysiologically high rates, leading to contraction fatigability. Rotating NMES pulses between multiple electrodes recruits subpopulations of MUs from each site, reducing MU firing rates and fatigability. This study was designed to determine whether rotating pulses between an increasing number of stimulation channels (cathodes) reduces contraction fatigability and increases the ability to generate torque during NMES. A secondary outcome was perceived discomfort. Fifteen neurologically intact volunteers completed four sessions. NMES was delivered over the quadriceps through 1 (NMES1), 2 (NMES2), 4 (NMES4) or 8 (NMES8) channels. Fatigability was assessed over 100 contractions (1-s on/1-s off) at an initial contraction amplitude that was 20% of a maximal voluntary contraction. Torque-frequency relationships were characterized over six frequencies from 20 to 120Hz. NMES4 and NMES8 resulted in less decline in peak torque (42 and 41%) over the 100 contractions than NMES1 and NMES2 (53 and 50% decline). Increasing frequency from 20 to 120Hz increased torque by 7, 13, 21 and 24% MVC, for NMES1, NMES2, NMES4 and NMES8, respectively. Perceived discomfort was highest during NMES8. NMES4 and NMES8 reduced contraction fatigability and generated larger contractions across a range of frequencies than NMES1 and NMES2. NMES8 produced the most discomfort, likely due to small electrodes and high current density. During NMES, more is not better and rotating pulses between four channels may be optimal to reduce contraction fatigability and produce larger contractions with minimal discomfort compared to conventional NMES configurations.
Highlights
Neuromuscular electrical stimulation (NMES) evokes contractions when pulses of current are applied through electrodes on the skin and it is used in diverse applications to enhance or maintain neuromuscular function (Sheffler and Chae 2007; Bickel et al 2011)
Over the course of the fatigue protocol for this participant, torque declined by 44%, 46%, 38%, and 32% during NMES1, NMES2, NMES4, and NMES8, respectively
This study was designed to investigate the effect of rotating NMES pulses between an increasing the number of stimulation channels on contraction fatigability, the relationship between torque and NMES frequency and discomfort
Summary
Neuromuscular electrical stimulation (NMES) evokes contractions when pulses of current are applied through electrodes on the skin and it is used in diverse applications to enhance or maintain neuromuscular function (Sheffler and Chae 2007; Bickel et al 2011). One way to reduce contraction fatigability during NMES is by rotating stimulation pulses between multiple electrodes. Rotating pulses between electrodes distributed over a muscle belly recruits MUs in different parts of the muscle sequentially, not synchronously, decreasing firing rates (Nguyen et al 2011; Sayenko et al 2014). This type of NMES has been given various names, the most descriptive of which may be spatially-distributed sequential stimulation (SDSS)
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