基于人体生理状态的新型髋关节屈伸辅助个性化策略

Biosensors Pub Date : 2024-08-27 DOI:10.3390/bios14090418
Beixian Wu, Chunjie Chen, Sheng Wang, Hui Chen, Zhuo Wang, Yao Liu, Tingwei He, Jiale Zhang, Xinyu Wu
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引用次数: 0

摘要

软质外衣已成为行走支持和康复训练的有力辅助工具。然而,大多数现有的软质外衣系统都依赖于预设的辅助模式,这些模式可能无法准确符合个人的生理状态和运动要求,从而导致用户体验和功效各不相同。虽然现有的人体在环(HIL)研究主要集中在优化代谢成本和扭矩差参数上,但密切反映人体生理状态的实时监测方法和动态显示行走效率的策略却明显缺乏。受此启发,我们开发了一种新型个性化动力辅助系统。该系统通过实时监测用户的生理和运动信号(包括心率(HR)、血氧饱和度(SpO2)和惯性测量单元(IMU)数据)来优化髋关节的动力辅助输出,并根据反馈来辅助髋关节屈曲。代谢消耗试验结果表明,基于生理状态监测控制(PSMC)系统的创新型软外穿衣在跑步机上以 3.5 公里/小时的速度行走时,与没有外穿衣辅助的行走相比,代谢消耗减少了 7.81%。此外,在不同强度的连续运动中,以每小时 2 公里、4 公里和 6 公里的速度行走时,代谢消耗水平分别降低了 5.1%、5.8% 和 8.2%。这些结果支持新型髋关节屈曲辅助软外装的设计,证明根据不同的生理状态施加不同的辅助力是减少代谢消耗的合理方法。
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A Novel Personalized Strategy for Hip Joint Flexion Assistance Based on Human Physiological State
Soft exosuits have emerged as potent assistive tools for walking support and rehabilitation training. However, most existing soft exosuit systems rely on preset assistance modes, which may not accurately align with individual physiological states and movement requirements, leading to variable user experiences and efficacy. While existing human-in-the-loop (HIL) research predominantly focuses on optimizing metabolic cost and torque difference parameters, there is a notable absence of real-time monitoring methods that closely reflect the human body’s physiological state and strategies that dynamically indicate walking efficiency. Motivated by this, we developed a novel personalized power-assist system. This system optimizes the power-assist output of the hip joint by monitoring the user’s physiological and motion signals in real time, including heart rate (HR), blood oxygen saturation (SpO2), and inertial measurement unit (IMU) data, to assist hip flexion based on feedback. The findings from a metabolic expenditure trial demonstrate that the innovative soft exosuit, which is based on a Physiological State Monitoring Control (PSMC) system, achieves a reduction of 7.81% in metabolic expenditure during treadmill walking at a speed of 3.5 km/h compared to walking without the assistance of the exosuit. Additionally, during continuous exercise with varying intensities, the metabolic consumption level is reduced by 5.1%, 5.8%, and 8.2% at speeds of 2, 4, and 6 km per hour, respectively. These results support the design of a novel hip flexion-assisting soft exosuit, demonstrating that applying different assistance forces in consideration of different physiological states is a reasonable approach to reducing metabolic consumption.
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