Abstract
Wearable devices have created new opportunities in healthcare and sport sciences by unobtrusively monitoring physiological signals. Textile polymer-based electrodes proved to be effective in detecting electrophysiological potentials but suffer mechanical fragility and low stretch resistance. The goal of this research is to develop and validate in dynamic conditions cost-effective and easily manufacturable electrodes characterized by adequate robustness and signal quality. We here propose an optimized screen printing technique for the fabrication of PEDOT:PSS-based textile electrodes directly into finished stretchable garments for surface electromyography (sEMG) applications. A sensorised stretchable leg sleeve was developed, targeting five muscles of interest in rehabilitation and sport science. An experimental validation was performed to assess the accuracy of signal detection during dynamic exercises, including sit-to-stand, leg extension, calf raise, walking, and cycling. The electrodes can resist up to 500 stretch cycles. Tests on five subjects revealed excellent contact impedance, and cross-correlation between sEMG envelopes simultaneously detected from the leg muscles by the textile and Ag/AgCl electrodes was generally greater than 0.9, which proves that it is possible to obtain good quality signals with performance comparable with disposable electrodes. An effective technique to embed polymer-based electrodes in stretchable smart garments was presented, revealing good performance for dynamic sEMG detections. The achieved results pave the way to the integration of unobtrusive electrodes, obtained by screen printing of conductive polymers, into technical fabrics for rehabilitation and sport monitoring, and in general where the detection of sEMG in dynamic conditions is necessary.
Highlights
The integration of unperceivable sensors and biopotential electrodes into fabrics for the development of easy-to-use, smart garments represents an important goal of wearable electronics
The stretching cycles determined a reduction in conductivity for all the tested electrodes, electrodes with 3-ink layers performed the best and were chosen for the fabrication of the leg sleeve for the experimental protocol
Statistical analysis revealed a significant effect of the electrode type on the noise values (p < 0.05), with textile electrodes being affected by a higher noise level and variability between measures
Summary
The integration of unperceivable sensors and biopotential electrodes into fabrics for the development of easy-to-use, smart garments represents an important goal of wearable electronics. Unobtrusive sensing using soft and conformable textile electrodes is the basis for the development of wearable devices to be applied in healthcare (e.g. for diagnosis [1], rehabilitation [2], prosthetics [3,4] and muscle activity monitoring [5]) and sport sciences [6], for professional athletes. From this perspective, the most relevant targeted biopotentials are electrocardiogram (ECG) [7] and surface electromyogram (sEMG) [8]. Textile electrodes based on the conductive polymer PEDOT:PSS have been extensively studied and employed as an alternative to commercial disposable pregelled electrodes, for sEMG [14,15] and ECG [16]
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