Advancements in Textile-Based sEMG Sensors for Muscle Fatigue Detection: A Journey from Material Evolution to Technological Integration

• Published in: ACS sensors Vol. 9; no. 9; pp. 4380 - 4401
• Main Authors: Medagedara, M. Hansika, Ranasinghe, Anuradha, Lalitharatne, Thilina D., Gopura, R. A. R. C., Nandasiri, Gayani K.
• Format: Journal Article
• Language: English
• Published: United States American Chemical Society 27.09.2024
• Subjects: textile sensors; medical textiles; sEMG; wearable sensors; sEMG evolution; textile electrodes; wearable technology; smart materials; muscle fatigue
• ISSN: 2379-3694; 2379-3694
• DOI: 10.1021/acssensors.4c00604

Textile-based surface electromyography (sEMG) electrodes have emerged as a prominent tool in muscle fatigue assessment, marking a significant shift toward innovative, noninvasive methods. This review examines the transition from metallic fibers to novel conductive polymers, elastomers, and advanced material-based electrodes, reflecting on the rapid evolution of materials in sEMG sensor technology. It highlights the pivotal role of materials science in enhancing sensor adaptability, signal accuracy, and longevity, crucial for practical applications in health monitoring, while examining the balance of clinical precision with user comfort. Additionally, it maps the global sEMG research landscape of diverse regional contributors and their impact on technological progress, focusing on the integration of Eastern manufacturing prowess with Western technological innovations and exploring both the opportunities and challenges in this global synergy. The integration of such textile-based sEMG innovations with artificial intelligence, nanotechnology, energy harvesting, and IoT connectivity is also anticipated as future prospects. Such advancements are poised to revolutionize personalized preventive healthcare. As the exploration of textile-based sEMG electrodes continues, the transformative potential not only promises to revolutionize integrated wellness and preventive healthcare but also signifies a seamless transition from laboratory innovations to real-world applications in sports medicine, envisioning the future of truly wearable material technologies.