Differentiable Biomechanics for Markerless Motion Capture in Upper Limb Stroke Rehabilitation: A Comparison With Optical Motion Capture
Tim Unger, Arash Sal Moslehian, J.D. Peiffer, Johannes Ullrich, Roger Gassert, Olivier Lambercy, R. Cotton, Chris Awai Easthope
Abstract
Marker-based Optical Motion Capture (OMC) paired with biomechanical modeling is currently considered the most precise and accurate method for measuring human movement kinematics. However, combining differentiable biomechanical modeling with Markerless Motion Capture (MMC) offers a promising approach to motion capture in clinical settings, requiring only minimal equipment, such as webcams, and minimal effort for data collection. This study compares key kinematic outcomes from biomechanically modeled MMC and OMC data in 15 individuals with stroke performing the drinking task, a functional task recommended for assessing upper limb movement quality. We observed a high level of agreement in kinematic trajectories between MMC and OMC, as indicated by high correlations (median r > 0.95 for the majority of kinematic trajectories) and median RMSE (root mean squared error) values ranging from 2∘-5∘ for joint angles, 0.04 m/s for end-effector velocity, and 6mm for trunk displacement. Trial-to-trial biases between OMC and MMC were consistent within participant sessions, with interquartile ranges of bias around 1-3∘ for joint angles, 0.01m/s in end-effector velocity, and approximately 3mm for trunk displacement. Our findings indicate that our MMC for arm tracking is approaching the accuracy of marker-based methods, supporting its potential for use in clinical settings. MMC could provide valuable insights into movement rehabilitation after stroke, potentially enhancing the effectiveness of rehabilitation strategies.