IEEE Transactions on Neural Systems and Rehabilitation Engineering (Jan 2024)

Design and Test of an Intraoral Electrode Grid for Tongue High-Density Electromyography

  • Alberto Botter,
  • Taian Vieira,
  • Chiara Busso,
  • Federica Vitali,
  • Marco Gazzoni,
  • Giacinto L. Cerone

DOI
https://doi.org/10.1109/TNSRE.2024.3434360
Journal volume & issue
Vol. 32
pp. 2805 – 2814

Abstract

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Tongue motor function is crucial in a wide range of basic activities and its impairment affects quality of life. The electrophysiological assessment of the tongue relies primarily on needle electromyography, which is limited by its invasiveness and inability to capture the concurrent activity of the different tongue muscles. This work aimed at developing an intraoral grid for high-density surface electromyography (HDsEMG) to non-invasively map the electrical excitation of tongue muscles. We developed a grid of $4\times 8$ electrodes deposited over an adhesive 8- $\mu $ m thick polyurethane membrane. The testing protocol was conducted on 7 healthy participants and included functional tasks (vowels articulation and tongue movements) aimed at activating different regions of the tongue. The electrical stability of contact was assessed by measuring electrode-tongue impedances before and after the tasks. The spatial amplitude distribution of global EMG and single motor unit action potentials (MUAPs) was characterized. Electrode-tongue impedance magnitude showed no significant changes in the pre-post comparison ( $58\pm 46$ k $\Omega $ vs. $67\pm 58$ k $\Omega $ at 50Hz). Contact stability was confirmed by the quality of the signals that allowed to quantify spatiotemporal characteristics of muscle activation during the different tasks. The analysis of the spatial distribution of individual MUAPs amplitude showed that they were confined to relatively small areas on the tongue surface (range: 0.5cm2 –3.9cm $^{{2}}\text {)}$ . A variety of different spatiotemporal MUAP patterns, likely due to the presence of different muscle compartments with different fiber orientations, were observed. Our results demonstrate that the developed electrode grid enables HDsEMG acquisition from the tongue during functional tasks, thus opening new possibilities in tongue muscle assessment both at global and single motor unit level.

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