影响脑瘫患者使用机器人踝关节外骨骼步态训练的神经肌肉反应的因素。

IF 2.5 4区 医学 Q1 REHABILITATION Assistive Technology Pub Date : 2023-11-02 Epub Date: 2022-10-04 DOI:10.1080/10400435.2022.2121324
Benjamin C Conner, Alyssa M Spomer, Katherine M Steele, Zachary F Lerner
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引用次数: 0

摘要

目前机器人步态训练干预措施发展的一个限制是了解预测治疗反应的因素。本研究的目的是探索可解释的机器学习方法贝叶斯加性回归树(BART)的应用,以确定影响脑瘫患者对阻力性踝关节外骨骼的神经肌肉反应的因素。8名CP患者(GMFCS I-III级,年龄12-18岁 年)在七次访问中使用阻力性踝关节外骨骼行走,同时我们测量了比目鱼肌的激活。BART模型是使用一组预测运动学、装置、研究和参与者指标开发的,这些指标被假设会影响比目鱼肌激活。型号(R2 = 0.94)发现,运动学对比目鱼肌激活的影响最大,但外骨骼阻力的大小、使用该设备的步态训练量和参与者级别的参数也有显著影响。为了优化CP患者外骨骼训练期间的神经肌肉参与,我们的分析强调了监测用户运动反应的重要性,特别是峰值站立期髋关节屈曲和踝关节背屈。我们展示了机器学习技术在增强我们对机器人步态训练结果的理解方面的实用性,试图提高未来干预措施的效果。
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Factors influencing neuromuscular responses to gait training with a robotic ankle exoskeleton in cerebral palsy.

A current limitation in the development of robotic gait training interventions is understanding the factors that predict responses to treatment. The purpose of this study was to explore the application of an interpretable machine learning method, Bayesian Additive Regression Trees (BART), to identify factors influencing neuromuscular responses to a resistive ankle exoskeleton in individuals with cerebral palsy (CP). Eight individuals with CP (GMFCS levels I - III, ages 12-18 years) walked with a resistive ankle exoskeleton over seven visits while we measured soleus activation. A BART model was developed using a predictor set of kinematic, device, study, and participant metrics that were hypothesized to influence soleus activation. The model (R2 = 0.94) found that kinematics had the largest influence on soleus activation, but the magnitude of exoskeleton resistance, amount of gait training practice with the device, and participant-level parameters also had substantial effects. To optimize neuromuscular engagement during exoskeleton training in individuals with CP, our analysis highlights the importance of monitoring the user's kinematic response, in particular, peak stance phase hip flexion and ankle dorsiflexion. We demonstrate the utility of machine learning techniques for enhancing our understanding of robotic gait training outcomes, seeking to improve the efficacy of future interventions.

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来源期刊
Assistive Technology
Assistive Technology REHABILITATION-
CiteScore
4.00
自引率
5.60%
发文量
40
期刊介绍: Assistive Technology is an applied, scientific publication in the multi-disciplinary field of technology for people with disabilities. The journal"s purpose is to foster communication among individuals working in all aspects of the assistive technology arena including researchers, developers, clinicians, educators and consumers. The journal will consider papers from all assistive technology applications. Only original papers will be accepted. Technical notes describing preliminary techniques, procedures, or findings of original scientific research may also be submitted. Letters to the Editor are welcome. Books for review may be sent to authors or publisher.
期刊最新文献
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