Biodynamic Modeling and Analysis of Human-Exoskeleton Interactions in Simulated Patient Handling Tasks

• Published in: Human factors Vol. 67; no. 7; pp. 641 - 655
• Main Authors: Chen, Yinong, Yin, Wei, Zheng, Liying, Mehta, Ranjana, Zhang, Xudong
• Format: Journal Article
• Language: English
• Published: Los Angeles, CA SAGE Publications 01.07.2025; Human Factors and Ergonomics Society
• Subjects: Adult; Biodynamics; Biomechanical Phenomena - physiology; Biomechanics; Biomechanics, Anthropometry, Work Physiology; Clinical trials; Ergonomics; Exoskeleton; Exoskeleton Device; Exoskeletons; Female; Handling; Humans; Lifting; Male; Modelling; Models, Biological; Moving and Lifting Patients; Musculoskeletal diseases; Patient handling; Shoulder; Task Performance and Analysis; Tractors; Young Adult; subject-specific biodynamic modeling; patient handling; musculoskeletal disorders; human-exoskeleton interaction
• ISSN: 0018-7208; 1547-8181; 1547-8181
• DOI: 10.1177/00187208241311271

Objective To investigate the biodynamics of human-exoskeleton interactions during patient handling tasks using a subject-specific modeling approach. Background Exoskeleton technology holds promise for mitigating musculoskeletal disorders caused by manual handling and most alarmingly by patient handling jobs. A deeper, more unified understanding of the biomechanical effects of exoskeleton use calls for advanced subject-specific models of complex, dynamic human-exoskeleton interactions. Methods Twelve sex-balanced healthy participants performed three simulated patient handling tasks along with a reference load-lifting task, with and without wearing the exoskeleton, while their full-body motion and ground reaction forces were measured. Subject-specific models were constructed using motion and force data. Biodynamic response variables derived from the models were analyzed to examine the effects of the exoskeleton. Model validation used load-lifting trials with known hand forces. Results The use of exoskeleton significantly reduced (19.7%–27.2%) the peak lumbar flexion moment but increased (26.4%–47.8%) the peak lumbar flexion motion, with greater moment percent reduction in more symmetric handling tasks; similarly affected the shoulder joint moments and motions but only during two more symmetric handling tasks; and significantly reduced the peak motions for the rest of the body joints. Conclusion Subject-specific biodynamic models simulating exoskeleton-assisted patient handling were constructed and validated, demonstrating that the exoskeleton effectively lessened the peak loading to the lumbar and shoulder joints as prime movers while redistributing more motions to these joints and less to the remaining joints. Application The findings offer new insights into biodynamic responses during exoskeleton-assisted patient handling, benefiting the development of more effective, possibly task- and individual-customized, exoskeletons.