TY - GEN
T1 - AI Micro Motion Sensors for Screening Sarcopenia-prone Elderly Subjects
AU - Wang, Keer
AU - Zhang, Hongyu
AU - Cheng, Clio Yuen Man
AU - Chen, Meng
AU - Lai, King Wai Chiu
AU - Or, Calvin Kalun
AU - Hu, Yong
AU - Vellaisamy, Arul Lenus Roy
AU - Lam, Cindy Lo Kuen
AU - Xi, Ning
AU - Lou, Vivian Weiqun
AU - Li, Wen Jung
N1 - Publisher Copyright:
© 2024 IEEE.
PY - 2024
Y1 - 2024
N2 - Sarcopenia, a condition characterized by age-related muscle mass and function decline, poses significant risks including falls, fractures, gait disorders, and even mortality. This study aimed to develop an AI motion sensor system utilizing micro inertial measurement units (μIMUs) to screen sarcopeniaprone elderly subjects. Subjects within the age range of 65-84 years performed single sit-To-stand and 5-Time chair stand while wearing two μIMUs. K-Nearest-Neighbours (KNN) algorithms were employed to collect and analyze motion data from the tests. The 53 subjects were categorized as either healthy or sarcopeniaprone, with the sarcopenia-prone group further classified into three levels based on their condition severity. The highest classification accuracy achieved was 94.64% for distinguishing between healthy and sarcopenia-prone subjects, and 90.44% for differentiating various sarcopenia-prone risk levels. This AI motion sensor system demonstrates potential as a cost-effective and accessible approach for large-scale sarcopenia screening. Further refinement of this method could enable remote health monitoring and telerehabilitation programs catering to older adults.
AB - Sarcopenia, a condition characterized by age-related muscle mass and function decline, poses significant risks including falls, fractures, gait disorders, and even mortality. This study aimed to develop an AI motion sensor system utilizing micro inertial measurement units (μIMUs) to screen sarcopeniaprone elderly subjects. Subjects within the age range of 65-84 years performed single sit-To-stand and 5-Time chair stand while wearing two μIMUs. K-Nearest-Neighbours (KNN) algorithms were employed to collect and analyze motion data from the tests. The 53 subjects were categorized as either healthy or sarcopeniaprone, with the sarcopenia-prone group further classified into three levels based on their condition severity. The highest classification accuracy achieved was 94.64% for distinguishing between healthy and sarcopenia-prone subjects, and 90.44% for differentiating various sarcopenia-prone risk levels. This AI motion sensor system demonstrates potential as a cost-effective and accessible approach for large-scale sarcopenia screening. Further refinement of this method could enable remote health monitoring and telerehabilitation programs catering to older adults.
UR - http://www.scopus.com/inward/record.url?scp=85197527628&partnerID=8YFLogxK
U2 - 10.1109/NSENS62142.2024.10561441
DO - 10.1109/NSENS62142.2024.10561441
M3 - Conference contribution
AN - SCOPUS:85197527628
T3 - Proceedings of the 3rd IEEE International Conference on Micro/Nano Sensors for AI, Healthcare and Robotics, NSENS 2024
SP - 107
EP - 111
BT - Proceedings of the 3rd IEEE International Conference on Micro/Nano Sensors for AI, Healthcare and Robotics, NSENS 2024
T2 - 3rd IEEE International Conference on Micro/Nano Sensors for AI, Healthcare and Robotics, NSENS 2024
Y2 - 2 March 2024 through 3 March 2024
ER -