基于加速度计的步态辅助神经假体步启动控制。

Q Medicine
Kevin M Foglyano, John R Schnellenberger, Rudi Kobetic, Lisa Lombardo, Gilles Pinault, Stephen Selkirk, Nathaniel S Makowski, Ronald J Triolo
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引用次数: 8

摘要

麻痹肌肉的电激活可以产生或增强中枢神经系统创伤后行走所需的关节运动。适当的刺激时机相对于残余的意志控制是有效影响活动的关键。本研究评估了三维加速度计和定制算法,用于检测具有明显不同病因、活动受限、手灵巧性和行走辅助设备的个体在行走过程中从自主运动到触发刺激的意图。三名中风后偏瘫或部分脊髓损伤患者表现出不同的步态缺陷,植入了多通道脉冲发生器,以提供髋关节、膝关节和踝关节的关节运动。集成在外部控制单元中的加速度计用于检测足跟撞击或助行器运动,无线加速度计用于检测拐杖撞击。为每个传感器位置开发了算法,通过个性化刺激模式检测步骤的意图。通过测试这些算法,在平地和不平坦地形上的检测精度都至少达到90%。所有参与者在社区中使用加速计触发的植入步态系统;验证/系统测试在医院完成。结果表明,安全、可靠和方便的基于加速度计的步启动可以实现,而不考虑特定的步态缺陷、手灵巧性和行走辅助。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Accelerometer-based step initiation control for gait-assist neuroprostheses.

Electrical activation of paralyzed musculature can generate or augment joint movements required for walking after central nervous system trauma. Proper timing of stimulation relative to residual volitional control is critical to usefully affecting ambulation. This study evaluates three-dimensional accelerometers and customized algorithms to detect the intent to step from voluntary movements to trigger stimulation during walking in individuals with significantly different etiologies, mobility limitations, manual dexterities, and walking aids. Three individuals with poststroke hemiplegia or partial spinal cord injury exhibiting varying gait deficits were implanted with multichannel pulse generators to provide joint motions at the hip, knee, and ankle. An accelerometer integrated into the external control unit was used to detect heel strike or walker movement, and wireless accelerometers were used to detect crutch strike. Algorithms were developed for each sensor location to detect intent to step to progress through individualized stimulation patterns. Testing these algorithms produced detection accuracies of at least 90% on both level ground and uneven terrain. All participants use their accelerometer-triggered implanted gait systems in the community; the validation/system testing was completed in the hospital. The results demonstrated that safe, reliable, and convenient accelerometer-based step initiation can be achieved regardless of specific gait deficits, manual dexterities, and walking aids.

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CiteScore
1.64
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