在日常生活中测量冻结步态：一种开源、可穿戴传感器方法。

Measuring freezing of gait during daily-life: an open-source, wearable sensors approach.

机构信息

Department of Neurology, School of Medicine, Oregon Health & Science University, 3181 SW Sam Jackson Park Road, OP-32, Portland, OR, 97239, USA.

Department of Sport, Exercise and Rehabilitation, Northumbria University, Newcastle upon Tyne, UK.

出版信息

J Neuroeng Rehabil. 2021 Jan 4;18(1):1. doi: 10.1186/s12984-020-00774-3.

DOI:10.1186/s12984-020-00774-3

PMID:33397401

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7784003/

Abstract

BACKGROUND

Although a growing number of studies focus on the measurement and detection of freezing of gait (FoG) in laboratory settings, only a few studies have attempted to measure FoG during daily life with body-worn sensors. Here, we presented a novel algorithm to detect FoG in a group of people with Parkinson's disease (PD) in the laboratory (Study I) and extended the algorithm in a second cohort of people with PD at home during daily life (Study II).

METHODS

In Study I, we described of our novel FoG detection algorithm based on five inertial sensors attached to the feet, shins and lumbar region while walking in 40 participants with PD. We compared the performance of the algorithm with two expert clinical raters who scored the number of FoG episodes from video recordings of walking and turning based on duration of the episodes: very short (< 1 s), short (2-5 s), and long (> 5 s). In Study II, a different cohort of 48 people with PD (with and without FoG) wore 3 wearable sensors on their feet and lumbar region for 7 days. Our primary outcome measures for freezing were the % time spent freezing and its variability.

RESULTS

We showed moderate to good agreement in the number of FoG episodes detected in the laboratory (Study I) between clinical raters and the algorithm (if wearable sensors were placed on the feet) for short and long FoG episodes, but not for very short FoG episodes. When extending this methodology to unsupervised home monitoring (Study II), we found that percent time spent freezing and the variability of time spent freezing differentiated between people with and without FoG (p < 0.05), and that short FoG episodes account for 69% of the total FoG episodes.

CONCLUSION

Our findings showed that objective measures of freezing in PD using inertial sensors on the feet in the laboratory are matching well with clinical scores. Although results found during daily life are promising, they need to be validated. Objective measures of FoG with wearable technology during community-living would be useful for managing this distressing feature of mobility disability in PD.

摘要

背景

尽管越来越多的研究关注于在实验室环境中对冻结步态（Freezing of gait，FoG）的测量和检测，但只有少数研究尝试使用穿戴式传感器在日常生活中测量 FoG。在这里，我们提出了一种新的算法，用于在实验室中检测一组帕金森病（Parkinson's disease，PD）患者的 FoG（研究 I），并将该算法扩展到第二组在家中日常生活中患有 PD 的患者（研究 II）。

方法

在研究 I 中，我们描述了我们的新 FoG 检测算法，该算法基于五个惯性传感器，分别贴附在脚部、小腿和腰部，以在 40 名 PD 患者行走时使用。我们将算法的性能与两名专家临床评分员进行了比较，评分员根据发作持续时间对视频记录中行走和转弯时 FoG 发作的次数进行评分：非常短（<1 s）、短（2-5 s）和长（>5 s）。在研究 II 中，另一组 48 名 PD 患者（有无 FoG）在脚部和腰部佩戴 3 个可穿戴传感器，持续 7 天。我们的主要冻结结果测量指标为冻结时间百分比及其变异性。

结果

我们发现，在实验室中（研究 I），临床评分员和算法（如果在脚部放置可穿戴传感器）检测到的 FoG 发作次数之间存在中度至良好的一致性，用于短和长 FoG 发作，但不适用于非常短 FoG 发作。当将此方法扩展到无人监督的家庭监测（研究 II）时，我们发现，冻结时间百分比和冻结时间变异性可区分有无 FoG 的患者（p<0.05），且短 FoG 发作占总 FoG 发作的 69%。

结论

我们的研究结果表明，使用脚部惯性传感器在实验室中对 PD 患者的冻结进行客观测量与临床评分非常吻合。虽然日常生活中发现的结果很有希望，但仍需要进一步验证。在社区生活中使用可穿戴技术进行 FoG 的客观测量对于管理 PD 中这种令人痛苦的移动障碍特征将非常有用。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/1651/7784003/2a22be8c9a31/12984_2020_774_Fig1_HTML.jpg

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在日常生活中测量冻结步态：一种开源、可穿戴传感器方法。

Measuring freezing of gait during daily-life: an open-source, wearable sensors approach.

机构信息

出版信息

BACKGROUND

METHODS

RESULTS

CONCLUSION

背景

方法

结果

结论

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