English

Wearable-informed generative digital avatars predict task-conditioned post-stroke locomotion

Computational Engineering, Finance, and Science 2026-01-06 v2 Artificial Intelligence

Abstract

Dynamic prediction of locomotor capacity after stroke could enable more individualized rehabilitation, yet current assessments largely provide static impairment scores and do not indicate whether patients can perform specific tasks such as slope walking or stair climbing. Here, we present a wearable-informed data-physics hybrid generative framework that reconstructs a stroke survivor's locomotor control from wearable inertial sensing and predicts task-conditioned post-stroke locomotion in new environments. From a single 20 m level-ground walking trial recorded by five IMUs, the framework personalizes a physics-based digital avatar using a healthy-motion prior and hybrid imitation learning, generating dynamically feasible, patient-specific movements for inclined walking and stair negotiation. Across 11 stroke inpatients, predicted postures reached 82.2% similarity for slopes and 69.9% for stairs, substantially exceeding a physics-only baseline. In a multicentre pilot randomized study (n = 21; 28 days), access to scenario-specific locomotion predictions to support task selection and difficulty titration was associated with larger gains in Fugl-Meyer lower-extremity scores than standard care (mean change 6.0 vs 3.7 points; p<0.05p < 0.05). These results suggest that wearable-informed generative digital avatars may augment individualized gait rehabilitation planning and provide a pathway toward dynamically personalized post-stroke motor recovery strategies.

Keywords

Cite

@article{arxiv.2512.14329,
  title  = {Wearable-informed generative digital avatars predict task-conditioned post-stroke locomotion},
  author = {Yanning Dai and Chenyu Tang and Ruizhi Zhang and Wenyu Yang and Yilan Zhang and Yuhui Wang and Junliang Chen and Xuhang Chen and Ruimou Xie and Yangyue Cao and Qiaoying Li and Jin Cao and Tao Li and Hubin Zhao and Yu Pan and Arokia Nathan and Xin Gao and Peter Smielewski and Shuo Gao},
  journal= {arXiv preprint arXiv:2512.14329},
  year   = {2026}
}

Comments

27 pages, 6 figures

R2 v1 2026-07-01T08:27:14.420Z