Artificial Intelligence in Cerebral Palsy Rehabilitation: Current Progress and Future Directions

Xin Chen; Yicheng Ban; Qingmei Lu; Xiaolin Long; Ying Liang; Yujie Mo

doi:10.26855/acc.2026.03.008

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ArticleOpen Access http://dx.doi.org/10.26855/acc.2026.03.008

Artificial Intelligence in Cerebral Palsy Rehabilitation: Current Progress and Future Directions

Xin Chen^1,2,#, Yicheng Ban^1,#, Qingmei Lu^1,*, Xiaolin Long¹, Ying Liang¹, Yujie Mo²

¹Youjiang Medical University for Nationalities, Baise 533000, Guangxi, China.

²National University of Singapore, Singapore 119077, Singapore.

^#These authors contributed equally to this work.

*Corresponding author: Qingmei Lu

This work was supported by the Guangxi Higher Education Young and Middle-aged Teachers’ Basic Scientific Research Ability Improvement Project (Grant No. 2021KY0551).

Published: March 31,2026

Abstract

Cerebral palsy (CP) is the most prevalent motor disability in childhood and is characterized by heterogeneous impairments in movement, posture, and associated functions. Conventional rehabilitation approaches, including physical, occupational, and speech therapy, as well as pharmacological and surgical interventions, have achieved partial success but remain limited by inter-patient variability, labor-intensive assessments, and constrained prognostic accuracy. Recent advances in artificial intelligence (AI) and machine learning (ML) offer new opportunities to address these challenges by enabling faster, more objective evaluations and by integrating large-scale multimodal data. Emerging applications span gait and posture analysis, electromyographic monitoring, neuroimaging, speech and cognitive rehabilitation, and clinical decision support, demonstrating improved efficiency, interpretability, and scalability. Nevertheless, many current models rely on retrospective or single-center datasets, raising concerns about generalizability, reproducibility, and clinical integration. This review synthesizes the current state of AI in CP rehabilitation, highlighting methodological innovations, clinical implications, and existing limitations. Future directions emphasize the need for robust external validation, interpretable models, and interdisciplinary frameworks that can facilitate translational impact. Collectively, this work underscores AI’s potential to complement traditional rehabilitation, providing more personalized, efficient, and clinically actionable strategies for individuals with CP.

Keywords

Artificial Intelligence; Machine Learning; Cerebral Palsy; Rehabilitation

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How to cite this paper

Artificial Intelligence in Cerebral Palsy Rehabilitation: Current Progress and Future Directions

How to cite this paper: Xin Chen, Yicheng Ban, Qingmei Lu, Xiaolin Long, Ying Liang, Yujie Mo. (2026) Artificial Intelligence in Cerebral Palsy Rehabilitation: Current Progress and Future Directions. Advances in Computer and Communication, 7(1), 52-66.

DOI: http://dx.doi.org/10.26855/acc.2026.03.008

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