KIINCE的开发：一种基于动力学反馈的机器人环境，用于研究神经肌肉协调以及人类站立和行走的康复。

Development of KIINCE: A kinetic feedback-based robotic environment for study of neuromuscular coordination and rehabilitation of human standing and walking.

作者信息

Boehm Wendy L, Gruben Kreg G

机构信息

Department of Biomedical Engineering, Northwestern University, Chicago, USA.

Department of Kinesiology, University of Wisconsin, Madison, USA.

出版信息

J Rehabil Assist Technol Eng. 2018 Sep 20;5:2055668318793585. doi: 10.1177/2055668318793585. eCollection 2018 Jan-Dec.

DOI:10.1177/2055668318793585

PMID:31191950

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6453043/

Abstract

INTRODUCTION

The objective of this article is to introduce the robotic platform KIINCE and its emphasis on the potential of kinetic objectives for studying and training human walking and standing. The device is motivated by the need to characterize and train lower limb muscle coordination to address balance deficits in impaired walking and standing.

METHODS

The device measures the forces between the user and his or her environment, particularly the force of the ground on the feet () that reflects lower limb joint torque coordination. In an environment that allows for exploration of the user's capabilities, various forms of real-time feedback guide neural training to produce appropriate for remaining upright. Control of the foot plate motion is configurable and may be user driven or prescribed. Design choices are motivated from theory of motor control and learning as well as empirical observations of during walking and standing.

RESULTS

Preliminary studies of impaired individuals demonstrate the feasibility and potential utility of patient interaction with kinetic immersive interface for neuromuscular coordination enhancement.

CONCLUSION

Applications include study and rehabilitation of standing and walking after injury, amputation, and neurological insult, with an initial focus on stroke discussed here.

摘要

引言

本文的目的是介绍机器人平台KIINCE及其对动力学目标在研究和训练人类行走与站立方面潜力的重视。该设备的研发动机是需要对下肢肌肉协调性进行表征和训练，以解决行走和站立功能受损时的平衡缺陷问题。

方法

该设备测量用户与其周围环境之间的力，特别是地面作用于脚部的力（），该力反映了下肢关节扭矩协调性。在一个允许探索用户能力的环境中，各种形式的实时反馈引导神经训练，以产生适合保持直立的（动作）。脚板运动的控制是可配置的，可以由用户驱动或预先设定。设计选择的依据是运动控制和学习理论以及对行走和站立过程中（相关情况）的实证观察。

结果

对功能受损个体的初步研究表明，患者与动力学沉浸式界面互动以增强神经肌肉协调性具有可行性和潜在效用。

结论

应用包括对受伤、截肢和神经损伤后站立和行走的研究与康复，本文初步重点讨论中风情况。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/6a56/6453043/6c26a0ce30ef/10.1177_2055668318793585-fig1.jpg

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KIINCE的开发：一种基于动力学反馈的机器人环境，用于研究神经肌肉协调以及人类站立和行走的康复。

Development of KIINCE: A kinetic feedback-based robotic environment for study of neuromuscular coordination and rehabilitation of human standing and walking.

作者信息

机构信息

出版信息

INTRODUCTION

METHODS

RESULTS

CONCLUSION

引言

方法

结果

结论

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