通过中风幸存者上肢主动活动范围预测痉挛：广义估计方程模型

Prediction of Spasticity through Upper Limb Active Range of Motion in Stroke Survivors: A Generalized Estimating Equation Model.

作者信息

Adeel Muhammad, Peng Chih-Wei, Lee I-Jung, Lin Bor-Shing

机构信息

The Master Program in Smart Healthcare Management, International College of Sustainability Innovations, National Taipei University, New Taipei City 237303, Taiwan.

School of Biomedical Engineering, College of Biomedical Engineering, Taipei Medical University, Taipei 11031, Taiwan.

出版信息

Bioengineering (Basel). 2023 Nov 1;10(11):1273. doi: 10.3390/bioengineering10111273.

DOI:10.3390/bioengineering10111273

PMID:38002397

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10669379/

Abstract

BACKGROUND

We aim to study the association between spasticity and active range of motion (ROM) during four repetitive functional tasks such as cone stacking (CS), fast flexion-extension (FFE), fast ball squeezing (FBS), and slow ball squeezing (SBS), and predicted spasticity models.

METHODS

An experimental study with control and stroke groups was conducted in a Medical Center. A total of sixty-four participants, including healthy control ( = 22; average age (years) = 54.68 ± 9.63; male/female = 12/10) and chronic stroke survivors ( = 42; average age = 56.83 ± 11.74; male/female = 32/10) were recruited. We employed a previously developed smart glove device mounted with multiple inertial measurement unit (IMU) sensors on the upper limbs of healthy and chronic stroke individuals. The recorded ROMs were used to predict subjective spasticity through generalized estimating equations (GEE) for the affected side.

RESULTS

The models have significant ( ≤ 0.05 *) prediction of spasticity for the elbow, thumb, index, middle, ring, and little fingers. Overall, during SBS and FFE activities, the maximum number of upper limb joints attained the greater average ROMs. For large joints, the elbow during CS and the wrist during FFE have the highest average ROMs, but smaller joints and the wrist have covered the highest average ROMs during FFE, FBS, and SBS activities.

CONCLUSIONS

Thus, it is concluded that CS can be used for spasticity assessment of the elbow, FFE for the wrist, and SBS, FFE, and FBS activities for the thumb and finger joints in chronic stroke survivors.

摘要

背景

我们旨在研究在四项重复性功能任务（如锥体堆叠（CS）、快速屈伸（FFE）、快速握球（FBS）和缓慢握球（SBS））过程中痉挛与主动活动范围（ROM）之间的关联，以及预测痉挛的模型。

方法

在一家医疗中心进行了一项包含对照组和中风组的实验研究。共招募了64名参与者，包括健康对照组（n = 22；平均年龄（岁）= 54.68 ± 9.63；男/女 = 12/10）和慢性中风幸存者（n = 42；平均年龄 = 56.83 ± 11.74；男/女 = 32/10）。我们使用了一种先前开发的智能手套设备，该设备在上肢健康个体和慢性中风个体上安装了多个惯性测量单元（IMU）传感器。记录的ROM用于通过广义估计方程（GEE）预测患侧的主观痉挛情况。

结果

这些模型对肘部、拇指、食指、中指、无名指和小指的痉挛具有显著（P≤0.05*）预测能力。总体而言，在SBS和FFE活动期间，上肢关节达到的平均ROM最大值更多。对于大关节，CS期间的肘部和FFE期间的腕部平均ROM最高，但在FFE、FBS和SBS活动期间，小关节和腕部的平均ROM最高。

结论

因此，得出结论，CS可用于慢性中风幸存者肘部痉挛的评估，FFE可用于腕部痉挛的评估，而SBS、FFE和FBS活动可用于拇指和手指关节痉挛的评估。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/37c7/10669379/d2a01c6f7938/bioengineering-10-01273-g001.jpg

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通过中风幸存者上肢主动活动范围预测痉挛：广义估计方程模型

Prediction of Spasticity through Upper Limb Active Range of Motion in Stroke Survivors: A Generalized Estimating Equation Model.

作者信息

机构信息

出版信息

BACKGROUND

METHODS

RESULTS

CONCLUSIONS

背景

方法

结果

结论

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