School of Health & Society, The University of Salford, UK.
School of Health & Society, The University of Salford, UK.
J Biomech. 2019 Apr 18;87:167-171. doi: 10.1016/j.jbiomech.2019.02.010. Epub 2019 Feb 20.
The Conventional Gait Model (CGM) needs to benefit from large investigations on localization of the hip joint centre (HJC). Incorrect positions from the native equations were demonstrated (Sangeux et al., 2014; Harrington et al., 2007). More accurate equations were proposed but their impact on kinematics and kinetic CGM outputs was never evaluated. This short communication aims at examining if adoption of new HJC equations would alter standard CGM outputs. Sixteen able bodied participants underwent a full 3-D optoelectronic gait analysis followed by a 3-D ultrasound localization of their hips. Data were processed through the open source python package pyCGM2 replicating kinematic and kinetic processing of the native CGM. Compared with 3D ultrasound location, Hara equations improved the accuracy of sagittal plane kinematics (0.6°) and kinetics (0.02 N m kg) for the hip. The worst case participant exhibited Harrington's equations reached a deviation of 3° for the sagittal kinematics. In the coronal plane, Hara and Harrington equations presented similar differences (1°) for the hip whilst Davis equations had the largest deviation for hip abduction (2.7°) and hip abductor moment (0.10 N m kg). Both Harrington and Hara equations improved the CGM location of the HJC. Hara equations improved results in the sagittal plane, plus utilise a single anthropometrics measurement, leg length, that may be more robust. However, neither set of equations had significant effect on kinematics. We reported some effects on kinetics, particularly in the coronal plane, which warrant caution in interpreting outputs using different sets of equations.
传统步态模型(CGM)需要受益于髋关节中心(HJC)定位的大量研究。已经证明了来自原始方程的不正确位置(Sangeux 等人,2014 年;Harrington 等人,2007 年)。提出了更准确的方程,但从未评估它们对运动学和动力学 CGM 输出的影响。本简讯旨在研究采用新的 HJC 方程是否会改变标准 CGM 输出。16 名健康参与者接受了全面的 3D 光电步态分析,然后对他们的臀部进行了 3D 超声定位。数据通过开源 Python 包 pyCGM2 进行处理,复制了本机 CGM 的运动学和动力学处理。与 3D 超声位置相比,Hara 方程提高了矢状面运动学(0.6°)和动力学(0.02 N m kg)的准确性。表现最差的参与者使用 Harrington 方程时,矢状面运动学的偏差达到 3°。在冠状面,Hara 和 Harrington 方程对髋关节的差异相似(1°),而 Davis 方程对髋关节外展(2.7°)和髋关节外展肌力矩(0.10 N m kg)的偏差最大。Hara 和 Harrington 方程均改善了 CGM 对 HJC 的定位。Hara 方程改善了矢状面的结果,并且仅使用了单个人体测量学测量值,即腿长,这可能更健壮。但是,两组方程都没有对运动学产生重大影响。我们报告了一些动力学方面的影响,特别是在冠状面,这在使用不同的方程组解释输出时需要谨慎。
