日常生活活动中膝关节的主动功能僵硬:用于改进假肢设计的一个参数。
Active functional stiffness of the knee joint during activities of daily living: a parameter for improved design of prosthetic limbs.
作者信息
Bayram Hande Argunsah, Chien Chih-Hao, Davis Brian L
机构信息
Department of Chemical and Biomedical Engineering, Cleveland State University, Cleveland, OH, USA; Department of Biomedical Engineering, Lerner Research Institute, Cleveland Clinic, Cleveland, OH, USA; Human Performance and Engineering Laboratory, Kessler Foundation, West Orange, NJ, USA; Department of Research, Children's Specialized Hospital, New Brunswick, NJ, USA.
Department of Chemical and Biomedical Engineering, Cleveland State University, Cleveland, OH, USA; Department of Biomedical Engineering, Lerner Research Institute, Cleveland Clinic, Cleveland, OH, USA.
出版信息
Clin Biomech (Bristol). 2014 Dec;29(10):1193-9. doi: 10.1016/j.clinbiomech.2014.09.004. Epub 2014 Sep 16.
BACKGROUND
Exploring knee joint physiological functional stiffness is crucial for improving the design of prosthetic legs that aim to mimic normal gait. This study hypothesizes that knee joint stiffness varies among different activities of daily living, additionally while the knee performs natural movements; the magnitude of the stiffness indicates the degree of energy storage element sufficiency in terms of harvesting/returning energy.
METHODS
This study examined sagittal plane knee moment vs. knee flexion angle curves from 12 able-bodied subjects during activities of daily living. Slopes of these curves were assessed to find the calculated stiffness during the peak energy return and harvest phases so that the activities, which can be performed when the prosthetic knee is supplemented by a spring, were identified.
FINDINGS
For the energy return and harvest phases, the stiffness varied between 0.006 and 0.046 Nm/kg deg. and 0 and 0.052 Nm/kg deg. respectively. The optimum energy return phase stiffness was 0.024 (SD 0.013) Nm/kg deg. and energy harvest phase stiffness was 0.011 (SD 0.018) Nm/kg deg.
INTERPRETATION
Knee joint stiffness varied significantly during activities of daily living, which indicated that a storage unit with a constant stiffness would not be sufficient in providing energy regenerative gait during all activities. However, by controlling the amount and timing of spring compression and release, an energy-regenerative prosthetic knee device could be developed during most of the activities. This study was directed to the development of a complete data set, which determined the torque-angle properties of the healthy knee joint.
背景
探索膝关节的生理功能刚度对于改进旨在模仿正常步态的假肢设计至关重要。本研究假设膝关节刚度在不同的日常生活活动中有所不同,此外,当膝关节进行自然运动时,刚度的大小表明了能量存储元件在收集/返回能量方面的充足程度。
方法
本研究检查了12名身体健全的受试者在日常生活活动期间矢状面膝关节力矩与膝关节屈曲角度的曲线。评估这些曲线的斜率,以找出在能量返回和收集峰值阶段的计算刚度,从而确定当假肢膝关节配备弹簧时可以进行的活动。
结果
在能量返回和收集阶段,刚度分别在0.006至0.046 Nm/kg度和0至0.052 Nm/kg度之间变化。最佳能量返回阶段刚度为0.024(标准差0.013)Nm/kg度,能量收集阶段刚度为0.011(标准差0.018)Nm/kg度。
解读
膝关节刚度在日常生活活动中变化显著,这表明具有恒定刚度的存储单元在所有活动期间不足以提供能量再生步态。然而,通过控制弹簧压缩和释放的量和时间,可以在大多数活动期间开发一种能量再生假肢膝关节装置。本研究旨在开发一个完整的数据集,该数据集确定了健康膝关节的扭矩-角度特性。
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