Effects of a Passive Back-Support Exosuit on Postural Control and Cognitive Performance During a Fatigue-Inducing Posture Maintenance Task

• Published in: Human factors Vol. 66; no. 11; pp. 2451 - 2467
• Main Authors: Kim, Jiwon, Kang, Sang Hyeon, Li, Jinfeng, Mirka, Gary A., Dorneich, Michael C.
• Format: Journal Article
• Language: English
• Published: Los Angeles, CA SAGE Publications 01.11.2024; Human Factors and Ergonomics Society
• Subjects: Adult; Cognition - physiology; Cognitive ability; Cognitive tasks; Data processing; Effectiveness; Exoskeleton; Exoskeleton Device; Exoskeletons; Fatigue; Fatigue tests; Female; Human performance; Humans; Information processing; Information systems; Integration; Maintenance; Male; Muscle fatigue; Muscle Fatigue - physiology; Muscles; Muscular fatigue; Performance evaluation; Postural Balance - physiology; Posture; Posture - physiology; Support systems; Task Performance and Analysis; Torso; Velocity; Workload; Workloads; Young Adult; information processing; exoskeleton; postural control; cognitive performance; muscle fatigue
• ISSN: 0018-7208; 1547-8181; 1547-8181
• DOI: 10.1177/00187208231221890

Objective To evaluate the effectiveness of passive back-support exosuit on postural control and cognitive performance during a fatigue-inducing posture maintenance task. Background Wearable support systems (exoskeletons/exosuits) reduce physical demands but may also influence postural control and cognitive performance by reducing muscular fatigue. Method Eighteen participants visited on two different days to test an exosuit system and performed dual-task cognitive assessments based on human information processing (information acquisition, information integration, and action implementation) while maintaining a 35° trunk flexion posture for 16 minutes. Center-of-pressure (CoP), cognitive performance, and perceived workload were recorded, while erector spinae muscle activity was captured to quantify muscle fatigue. Results The exosuit was effective in reducing erector spinae muscle fatigue during the static posture maintenance task (61% less in Δmedian frequency: −9.5 Hz (EXO-Off) versus −3.7 Hz (EXO-On)). The fatigue-inducing task increased CoP velocity as a function of time (29% greater: 9.3 mm/sec (pre) versus 12.0 mm/sec (post)), and exosuit use decreased CoP velocity (23% less: 12.1 mm/sec (EXO-Off) versus 9.4 mm/sec (EXO-On)). The exosuit was also effective at mitigating cognitive degradation, as evidenced by a higher hit-to-signal ratio (8% greater: 81.3 (EXO-Off) versus 87.9 (EXO-On)) in the information integration task and reducing perceived workload in all stages of human information processing. Conclusion Exosuit provided benefits of postural control and information integration processing during a 16-min static posture maintenance task. Application Torso exoskeletons/suits can have positive implications for occupations with concurrent physical and cognitive demands.