CAS Key Laboratory of Human-Machine Intelligence-Synergy Systems, Shenzhen Institute of Advanced Technology, Chinese Academy of Sciences, Shenzhen, 518055, China.
Key Laboratory of Road Construction Technology and Equipment (Ministry of Education), School of Mechanical Engineering, Chang'an University, Xi'an, 710064, China.
Med Biol Eng Comput. 2024 Dec;62(12):3841-3853. doi: 10.1007/s11517-024-03171-3. Epub 2024 Jul 24.
The estimation of joint contact forces in musculoskeletal multibody dynamics models typically requires the use of expensive and time-consuming technologies, such as reflective marker-based motion capture (Mocap) system. In this study, we aim to propose a more accessible and cost-effective solution that utilizes the dual smartphone videos (SPV)-driven musculoskeletal multibody dynamics modeling workflow to estimate the lower limb mechanics. Twelve participants were recruited to collect marker trajectory data, force plate data, and motion videos during walking and running. The smartphone videos were initially analyzed using the OpenCap platform to identify key joint points and anatomical markers. The markers were used as inputs for the musculoskeletal multibody dynamics model to calculate the lower limb joint kinematics, joint contact forces, and ground reaction forces, which were then evaluated by the Mocap-based workflow. The root mean square error (RMSE), mean absolute deviation (MAD), and Pearson correlation coefficient (ρ) were adopted to evaluate the results. Excellent or strong Pearson correlations were observed in most lower limb joint angles (ρ = 0.74 ~ 0.94). The averaged MADs and RMSEs for the joint angles were 1.93 ~ 6.56° and 2.14 ~ 7.08°, respectively. Excellent or strong Pearson correlations were observed in most lower limb joint contact forces and ground reaction forces (ρ = 0.78 ~ 0.92). The averaged MADs and RMSEs for the joint lower limb joint contact forces were 0.18 ~ 1.07 bodyweight (BW) and 0.28 ~ 1.32 BW, respectively. Overall, the proposed smartphone video-driven musculoskeletal multibody dynamics simulation workflow demonstrated reliable accuracy in predicting lower limb mechanics and ground reaction forces, which has the potential to expedite gait dynamics analysis in a clinical setting.
肌肉骨骼多体动力学模型中关节接触力的估计通常需要使用昂贵且耗时的技术,例如基于反光标记的运动捕捉(Mocap)系统。在这项研究中,我们旨在提出一种更易于访问和更具成本效益的解决方案,该方案利用双智能手机视频(SPV)驱动的肌肉骨骼多体动力学建模工作流程来估计下肢力学。 招募了 12 名参与者来收集标记轨迹数据、力板数据和步行和跑步时的运动视频。 使用 OpenCap 平台对智能手机视频进行了初步分析,以识别关键关节点和解剖标记。 将标记用作肌肉骨骼多体动力学模型的输入,以计算下肢关节运动学、关节接触力和地面反作用力,然后通过基于 Mocap 的工作流程对其进行评估。 采用均方根误差(RMSE)、平均绝对偏差(MAD)和皮尔逊相关系数(ρ)来评估结果。 大多数下肢关节角度都观察到极好或强的皮尔逊相关性(ρ=0.740.94)。 关节角度的平均 MAD 和 RMSE 分别为 1.936.56°和 2.147.08°。 大多数下肢关节接触力和地面反作用力都观察到极好或强的皮尔逊相关性(ρ=0.780.92)。 下肢关节接触力的平均 MAD 和 RMSE 分别为 0.181.07 体重(BW)和 0.281.32 BW。 总体而言,所提出的智能手机视频驱动的肌肉骨骼多体动力学模拟工作流程在预测下肢力学和地面反作用力方面表现出可靠的准确性,这有可能加速临床环境中的步态动力学分析。
