JMIR Medical Informatics (Apr 2024)

Mining Clinical Notes for Physical Rehabilitation Exercise Information: Natural Language Processing Algorithm Development and Validation Study

  • Sonish Sivarajkumar,
  • Fengyi Gao,
  • Parker Denny,
  • Bayan Aldhahwani,
  • Shyam Visweswaran,
  • Allyn Bove,
  • Yanshan Wang

DOI
https://doi.org/10.2196/52289
Journal volume & issue
Vol. 12
p. e52289

Abstract

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BackgroundThe rehabilitation of a patient who had a stroke requires precise, personalized treatment plans. Natural language processing (NLP) offers the potential to extract valuable exercise information from clinical notes, aiding in the development of more effective rehabilitation strategies. ObjectiveThis study aims to develop and evaluate a variety of NLP algorithms to extract and categorize physical rehabilitation exercise information from the clinical notes of patients who had a stroke treated at the University of Pittsburgh Medical Center. MethodsA cohort of 13,605 patients diagnosed with stroke was identified, and their clinical notes containing rehabilitation therapy notes were retrieved. A comprehensive clinical ontology was created to represent various aspects of physical rehabilitation exercises. State-of-the-art NLP algorithms were then developed and compared, including rule-based, machine learning–based algorithms (support vector machine, logistic regression, gradient boosting, and AdaBoost) and large language model (LLM)–based algorithms (ChatGPT [OpenAI]). The study focused on key performance metrics, particularly F1-scores, to evaluate algorithm effectiveness. ResultsThe analysis was conducted on a data set comprising 23,724 notes with detailed demographic and clinical characteristics. The rule-based NLP algorithm demonstrated superior performance in most areas, particularly in detecting the “Right Side” location with an F1-score of 0.975, outperforming gradient boosting by 0.063. Gradient boosting excelled in “Lower Extremity” location detection (F1-score: 0.978), surpassing rule-based NLP by 0.023. It also showed notable performance in the “Passive Range of Motion” detection with an F1-score of 0.970, a 0.032 improvement over rule-based NLP. The rule-based algorithm efficiently handled “Duration,” “Sets,” and “Reps” with F1-scores up to 0.65. LLM-based NLP, particularly ChatGPT with few-shot prompts, achieved high recall but generally lower precision and F1-scores. However, it notably excelled in “Backward Plane” motion detection, achieving an F1-score of 0.846, surpassing the rule-based algorithm’s 0.720. ConclusionsThe study successfully developed and evaluated multiple NLP algorithms, revealing the strengths and weaknesses of each in extracting physical rehabilitation exercise information from clinical notes. The detailed ontology and the robust performance of the rule-based and gradient boosting algorithms demonstrate significant potential for enhancing precision rehabilitation. These findings contribute to the ongoing efforts to integrate advanced NLP techniques into health care, moving toward predictive models that can recommend personalized rehabilitation treatments for optimal patient outcomes.