用于膝关节屈伸监测的可穿戴环形传感器:人体动态测量

IF 2.7 Q3 ENGINEERING, BIOMEDICAL
Ian Anderson;Christopher Cosma;Yingzhe Zhang;Vigyanshu Mishra;Asimina Kiourti
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引用次数: 0

摘要

目标我们最近推出了一类用于关节弯曲监测的新型可穿戴环形传感器,克服了最先进技术的局限性。我们之前的研究报告了在圆柱形幻肢上使用刚性传感器进行静态场景下的概念验证。在这项工作中,我们首次在动态场景下对人体受试者使用我们的传感器进行了评估,使用的是基于纺织品的灵活原型,并与网络分析仪相连。此外,我们还展示了一个不固定的版本,并在模型上进行了验证,旨在实现完全可穿戴的设计。方法:使用三种动态活动(行走、快步走和完全屈伸,均在原地进行)在十(10)名成人身上验证系留传感器。非系留传感器则在一个以随机速度手动弯曲的圆柱形模型上进行验证。开发了一种校准机制来得出传感器测量的角度。然后使用均方根误差(RMSE)和皮尔逊相关系数作为度量标准,将这些角度与光探测和测距(LiDAR)深度相机同时捕获的黄金标准角度进行比较。结果:我们发现与黄金标准角度的相关性极佳(≥ 0.981)。该传感器在步行时的 RMSE 为 4.463° ± 1.266°,在快走时为 5.541° ± 2.082°,在完全屈伸活动中为 3.657° ± 1.815°,在模型弯曲测试中为 0.670° ± 0.366°。结论:在人体受试者身上,与其他可穿戴式屈曲传感器相比,系留式传感器达到了类似甚至略高的均方根误差,而在模型上,非系留式传感器则达到了极佳的均方根误差。同时,我们的传感器长期可靠,不会受伤,也不会妨碍自然运动。我们的研究结果为未来提高角度分辨率和实现完全可穿戴设计奠定了基础,同时还保持了上述与最先进技术相比的优势。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Wearable Loop Sensors for Knee Flexion Monitoring: Dynamic Measurements on Human Subjects
Goals: We have recently introduced a new class of wearable loop sensors for joint flexion monitoring that overcomes limitations in the state-of-the-art. Our previous studies reported a proof-of-concept on a cylindrical phantom limb, under static scenarios and with a rigid sensor. In this work, we evaluate our sensors, for the first time, on human subjects, under dynamic scenarios, using a flexible textile-based prototype tethered to a network analyzer. An untethered version is also presented and validated on phantoms, aiming towards a fully wearable design. Methods: Three dynamic activities (walking, brisk walking, and full flexion/extension, all performed in place) are used to validate the tethered sensor on ten (10) adults. The untethered sensor is validated upon a cylindrical phantom that is bent manually at random speed. A calibration mechanism is developed to derive the sensor-measured angles. These angles are then compared to gold-standard angles simultaneously captured by a light detection and ranging (LiDAR) depth camera using root mean square error (RMSE) and Pearson's correlation coefficient as metrics. Results: We find excellent correlation (≥ 0.981) to gold-standard angles. The sensor achieves an RMSE of 4.463° ± 1.266° for walking, 5.541° ± 2.082° for brisk walking, 3.657° ± 1.815° for full flexion/extension activities, and 0.670° ± 0.366° for the phantom bending test. Conclusion: The tethered sensor achieves similar to slightly higher RMSE as compared to other wearable flexion sensors on human subjects, while the untethered version achieves excellent RMSE on the phantom model. Concurrently, our sensors are reliable over time and injury-safe, and do not obstruct natural movement. Our results set the ground for future improvements in angular resolution and for realizing fully wearable designs, while maintaining the abovementioned advantages over the state-of-the-art.
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来源期刊
CiteScore
9.50
自引率
3.40%
发文量
20
审稿时长
10 weeks
期刊介绍: The IEEE Open Journal of Engineering in Medicine and Biology (IEEE OJEMB) is dedicated to serving the community of innovators in medicine, technology, and the sciences, with the core goal of advancing the highest-quality interdisciplinary research between these disciplines. The journal firmly believes that the future of medicine depends on close collaboration between biology and technology, and that fostering interaction between these fields is an important way to advance key discoveries that can improve clinical care.IEEE OJEMB is a gold open access journal in which the authors retain the copyright to their papers and readers have free access to the full text and PDFs on the IEEE Xplore® Digital Library. However, authors are required to pay an article processing fee at the time their paper is accepted for publication, using to cover the cost of publication.
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