利用个性化因果网络模拟自由生活环境中中风后步态控制的异质性

IF 4.8 2区 医学 Q2 ENGINEERING, BIOMEDICAL
Yuki Nishi;Koki Ikuno;Yusaku Takamura;Yuji Minamikawa;Shu Morioka
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引用次数: 0

摘要

中风后步态控制是一个复杂的问题,现有的步态模型往往无法解释步态的异质性和连续性。精确评估自由生活环境中的步速可调性和步态不稳定性对于了解卒中后步态功能障碍患者如何面对不同环境和情境非常重要。本研究旨在探索中风患者在自由生活步态控制中的个体因果相互作用。为此,50 名中风患者在自由生活环境中,在第五腰椎(L5)上佩戴加速度计 24 小时。根据加速度数据计算出的同时点和时间点的时空步态参数生成了独立的有向无环图(DAG)。光谱聚类和贝叶斯模型比较被用来描述 DAG 的特征。最后,通过贝叶斯逻辑分析对 DAG 模式进行解释。光谱聚类从 DAG 中识别出三个最佳聚类。聚类 1 包括中度中风患者,他们表现出高度步态不对称和步态不稳定,主要根据步幅调整步速。第 2 组包括轻度中风患者,他们主要根据步长调整步速。第 3 组包括主要根据步长和步幅调整步速的轻度卒中患者。这三个群组可根据四个变量进行准确分类:步速的 Ashman's D、Fugl-Meyer 评估、步速时间不对称和步长。步态控制的不同 DAG 模式表明了步态模式的异质性和中风患者功能的多样性。了解步态功能之间的理论相互作用将为高度定制化康复奠定基础。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Modeling the Heterogeneity of Post-Stroke Gait Control in Free-Living Environments Using a Personalized Causal Network
Post-stroke gait control is a complex, often fail to account for the heterogeneity and continuity of gait in existing gait models. Precisely evaluating gait speed adjustability and gait instability in free-living environments is important to understand how individuals with post-stroke gait dysfunction approach diverse environments and contexts. This study aimed to explore individual causal interactions in the free-living gait control of persons with stroke. To this end, fifty persons with stroke wore an accelerometer on the fifth lumbar vertebra (L5) for 24 h in a free-living environment. Individually directed acyclic graphs (DAGs) were generated based on the spatiotemporal gait parameters at contemporaneous and temporal points calculated from the acceleration data. Spectral clustering and Bayesian model comparison were used to characterize the DAGs. Finally, the DAG patterns were interpreted via Bayesian logistic analysis. Spectral clustering identified three optimal clusters from the DAGs. Cluster 1 included persons with moderate stroke who showed high gait asymmetry and gait instability and primarily adjusted gait speed based on cadence. Cluster 2 included individuals with mild stroke who primarily adjusted their gait speed based on step length. Cluster 3 comprised individuals with mild stroke who primarily adjusted their gait speed based on both step length and cadence. These three clusters could be accurately classified based on four variables: Ashman’s D for step velocity, Fugl-Meyer Assessment, step time asymmetry, and step length. The diverse DAG patterns of gait control identified suggest the heterogeneity of gait patterns and the functional diversity of persons with stroke. Understanding the theoretical interactions between gait functions will provide a foundation for highly tailored rehabilitation.
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来源期刊
CiteScore
8.60
自引率
8.20%
发文量
479
审稿时长
6-12 weeks
期刊介绍: Rehabilitative and neural aspects of biomedical engineering, including functional electrical stimulation, acoustic dynamics, human performance measurement and analysis, nerve stimulation, electromyography, motor control and stimulation; and hardware and software applications for rehabilitation engineering and assistive devices.
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