Integrating subject-specific workspace constraint and performance-based control strategy in robot-assisted rehabilitation.

IF 3.2 3区 医学 Q2 NEUROSCIENCES
Frontiers in Neuroscience Pub Date : 2024-10-30 eCollection Date: 2024-01-01 DOI:10.3389/fnins.2024.1473755
Qing Miao, Song Min, Cui Wang, Yi-Feng Chen
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引用次数: 0

Abstract

Introduction: The robot-assistive technique has been widely developed in the field of neurorehabilitation for enhancement of neuroplasticity, muscle activity, and training positivity. To improve the reliability and feasibility in this patient-robot interactive context, motion constraint methods and adaptive assistance strategies have been developed to guarantee the movement safety and promote the training effectiveness based on the user's movement information. Unfortunately, few works focus on customizing quantitative and appropriate workspace for each subject in passive/active training mode, and how to provide the precise assistance by considering movement constraints to improve human active participation should be further delved as well.

Methods: This study proposes an integrated framework for robot-assisted upper-limb training. A human kinematic upper-limb model is built to achieve a quantitative human-robot interactive workspace, and an iterative learning-based repulsive force field is developed to balance the compliant degrees of movement freedom and constraint. On this basis, a radial basis function neural network (RBFNN)-based control structure is further explored to obtain appropriate robotic assistance. The proposed strategy was preliminarily validated for bilateral upper-limb training with an end-effector-based robotic system.

Results: Experiments on healthy subjects are enrolled to validate the safety and feasibility of the proposed framework. The results show that the framework is capable of providing personalized movement workspace to guarantee safe and natural motion, and the RBFNN-based control structure can rapidly converge to the appropriate robotic assistance for individuals to efficiently complete various training tasks.

Discussion: The integrated framework has the potential to improve outcomes in personalized movement constraint and optimized robotic assistance. Future studies are necessary to involve clinical application with a larger sample size of patients.

在机器人辅助康复中整合特定对象工作空间约束和基于性能的控制策略。
简介机器人辅助技术已在神经康复领域得到广泛应用,以增强神经可塑性、肌肉活动和训练的积极性。为了提高这种病人-机器人互动情境的可靠性和可行性,人们开发了运动约束方法和自适应辅助策略,以保证运动安全,并根据用户的运动信息提高训练效果。遗憾的是,很少有研究关注在被动/主动训练模式下为每个受试者定制定量和合适的工作空间,而如何通过考虑运动约束提供精确辅助以提高人类的主动参与度也有待进一步深入研究:本研究提出了机器人辅助上肢训练的综合框架。方法:本研究提出了机器人辅助上肢训练的综合框架,通过建立人体上肢运动学模型来实现定量的人机交互工作空间,并开发了基于迭代学习的排斥力场来平衡顺应运动自由度和约束。在此基础上,进一步探索了基于径向基函数神经网络(RBFNN)的控制结构,以获得适当的机器人辅助。在使用基于末端执行器的机器人系统进行双侧上肢训练时,对所提出的策略进行了初步验证:对健康受试者进行了实验,以验证所提框架的安全性和可行性。结果表明,该框架能够提供个性化的运动工作空间,保证运动的安全性和自然性,基于 RBFNN 的控制结构能够快速收敛到适当的机器人辅助,帮助个体高效地完成各种训练任务:综合框架有望提高个性化运动约束和优化机器人辅助的效果。未来的研究有必要以更大的患者样本量进行临床应用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Frontiers in Neuroscience
Frontiers in Neuroscience NEUROSCIENCES-
CiteScore
6.20
自引率
4.70%
发文量
2070
审稿时长
14 weeks
期刊介绍: Neural Technology is devoted to the convergence between neurobiology and quantum-, nano- and micro-sciences. In our vision, this interdisciplinary approach should go beyond the technological development of sophisticated methods and should contribute in generating a genuine change in our discipline.
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