Abstract
In surface electromyography (surface EMG, or S-EMG), conduction velocity (CV) refers to the velocity at which the motor unit action potentials (MUAPs) propagate along the muscle fibers, during contractions. The CV is related to the type and diameter of the muscle fibers, ion concentration, pH, and firing rate of the motor units (MUs). The CV can be used in the evaluation of contractile properties of MUs, and of muscle fatigue. The most popular methods for CV estimation are those based on maximum likelihood estimation (MLE). This work proposes an algorithm for estimating CV from S-EMG signals, using digital image processing techniques. The proposed approach is demonstrated and evaluated, using both simulated and experimentally-acquired multichannel S-EMG signals. We show that the proposed algorithm is as precise and accurate as the MLE method in typical conditions of noise and CV. The proposed method is not susceptible to errors associated with MUAP propagation direction or inadequate initialization parameters, which are common with the MLE algorithm. Image processing -based approaches may be useful in S-EMG analysis to extract different physiological parameters from multichannel S-EMG signals. Other new methods based on image processing could also be developed to help solving other tasks in EMG analysis, such as estimation of the CV for individual MUs, localization and tracking of innervation zones, and study of MU recruitment strategies.
Highlights
In surface electromyography, conduction velocity (CV) refers to the velocity at which the motor unit action potentials (MUAPs) propagate along the muscle fibers, during contractions
For 16 dB signal-to-noise ratio (SNR) signals (Fig. 6b), both, maximum likelihood estimation (MLE) and image processing estimation (IPE) methods have similar behavior, with root mean squared error (RMSE) decreasing while the number channels used to CV estimation increases
When the CV was 3, 4 or 5 m/s, and the SNR was high (≥16 dB), the proposed IPE algorithm was as precise and accurate as the MLE method proposed by Farina et al [12]
Summary
In surface electromyography (surface EMG, or S-EMG), conduction velocity (CV) refers to the velocity at which the motor unit action potentials (MUAPs) propagate along the muscle fibers, during contractions. MUAPs propagate in the direction that causes the membrane voltage of muscle fiber cells to approach and surpass the threshold for excitation, causing the action potential to move [1]. This propagation occurs along the direction of the muscle fibers, and originates from the innervation zone (IZ) in opposing directions, towards the tendinous regions. CV can be used to supplement the information at the muscle’s fiber level obtained with needle EMG [10]. Van der Hoven studied CV in patients with amyotrophic lateral sclerosis using needle and S-EMG and discovered that these patients presents increased CV and decreased median frequency [11]
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