Integration of Motor Unit Filters for Enhanced Surface Electromyogram Decomposition During Varying Force Isometric Contraction

• Published in: IEEE transactions on neural systems and rehabilitation engineering Vol. 32; pp. 2905 - 2913
• Main Authors: Xia, Miaojuan, Chen, Chen, Sheng, Xinjun, Ding, Han
• Format: Journal Article
• Language: English
• Published: United States IEEE 2024
• Subjects: action potential; Action potentials; Action Potentials - physiology; Adult; Algorithms; Computer Simulation; Decoding; decomposition; Discharges (electric); Electromyography - methods; excitation level; Female; Filters; firing pattern; Force; Forearm - physiology; high-density electromyogram; Humans; Isometric Contraction - physiology; Male; Motor Neurons - physiology; Motor unit (MU); Motors; Muscle, Skeletal - physiology; Recruitment, Neurophysiological - physiology; Signal Processing, Computer-Assisted; Vectors; Young Adult
• ISSN: 1534-4320; 1558-0210; 1558-0210
• DOI: 10.1109/TNSRE.2024.3438770

Muscles generate varying levels of force by recruiting different numbers of motor units (MUs), and as the force increases, the number of recruited MUs gradually rises. However, current decoding methods encounter difficulties in maintaining a stable and consistent growth trend in MU numbers with increasing force. In some instances, an unexpected reduction in the number of MUs can even be observed as force intensifies. To address this issue, in this study, we propose an enhanced decoding method that adaptively reutilizes MU filters. Specifically, in addition to the normal decoding process, we introduced an additional procedure where MU filters are reused to initialize the algorithm. The MU filters are iterated and adapted to the new signals, aiming to decode motor units that were actually activated but cannot be identified due to heavy superimposition. We tested our method on both simulated and experimental surface electromyogram (sEMG) signals. We simulated isometric signals (10%-70%) with known MU firing patterns using experimentally recorded MU action potentials from forearm muscles and compared the decomposition results to two baseline approaches: convolution kernel compensation (CKC) and fast independent component analysis (fastICA). Our method increased the decoded MU number by a rate of 135.4% <inline-formula> <tex-math notation="LaTeX">\pm ~62.5 </tex-math></inline-formula>% and 63.6% <inline-formula> <tex-math notation="LaTeX">\pm ~20.2 </tex-math></inline-formula>% for CKC and fastICA, respectively, across different signal-to-noise ratios. The sensitivity and precision for MUs decomposed using the enhanced method remained at the same accuracy level (p <0.001) as those of normally decoded MUs. For the experimental signals, eight healthy subjects performed hand movements at five different force levels (10%-90%), during which sEMG signals were recorded and decomposed. The results indicate that the enhanced process increased the number of decoded MUs by 21.8% <inline-formula> <tex-math notation="LaTeX">\pm ~10.9 </tex-math></inline-formula>% across all subjects. We discussed the possibility of fully capturing all activated motor units by appropriately reusing previously decoded MU filters and improving the balance of activated motor unit numbers across varying excitation levels.