Design of a brain controlled hand exoskeleton for patients with motor neuron diseases

Mazoon S. Al Maamari, Salma S. Al Badi, A. Saleem, M. Mesbah, E. Hassan
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引用次数: 6

Abstract

Patients suffering with motor neuron diseases (MND) are characterized by their inability to control essential voluntary muscle activity. This situation may lead to what is known as Locked-in syndrome (LIS). As the name suggests, LIS describes the state of being locked inside a paralyzed body with a functioning mind. With recent advances in robotics and signal processing technologies, patients with motor neuron disease may be able to partially overcome their disability and regain some control over their external environments. In this paper, we propose a design for brain's controlled hand exoskeleton. The proposed system uses a dual loop control, namely the brain-hand control and a local (hand) force control. The hand exoskeleton design consists of three main parts: four fingers with a three-layered sliding spring mechanism, an extension to fix the thumb of the patient and the main body which connects all the fingers with the linear actuator. The proposed system is implemented and tested successfully. Two actions are performed, namely grasping and releasing a light foam ball. After a training period, the brain-controlled exoskeleton was able to perform the two actions accurately and smoothly.
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为运动神经元疾病患者设计脑控手外骨骼
运动神经元疾病(MND)患者的特点是无法控制基本的随意肌活动。这种情况可能导致闭锁综合征(LIS)。顾名思义,LIS描述的是一种被锁在瘫痪的身体里,但大脑功能正常的状态。随着机器人技术和信号处理技术的最新进展,运动神经元疾病患者可能能够部分克服他们的残疾,并重新获得对外部环境的一些控制。本文提出了一种脑控手外骨骼的设计方案。该系统采用双回路控制,即脑手控制和局部(手)力控制。手外骨骼设计由三个主要部分组成:带有三层滑动弹簧机构的四个手指,固定患者拇指的延伸部分以及连接所有手指的线性执行器的主体。该系统已成功实现并经过测试。执行两个动作,即抓握和释放轻泡沫球。经过一段时间的训练,大脑控制的外骨骼能够准确而平稳地完成这两个动作。
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