Machine learning for classifying chronic ankle instability based on ankle strength, range of motion, postural control and anatomical deformities in delivery service workers with a history of lateral ankle sprains

Ui-Jae Hwang; Oh-Yun Kwon; Jun-Hee Kim; Gyeong-Tae Gwak

doi:10.1016/j.msksp.2024.103230

Machine learning for classifying chronic ankle instability based on ankle strength, range of motion, postural control and anatomical deformities in delivery service workers with a history of lateral ankle sprains

Musculoskelet Sci Pract. 2024 Nov 19:75:103230. doi: 10.1016/j.msksp.2024.103230. Online ahead of print.

Authors

Ui-Jae Hwang¹, Oh-Yun Kwon², Jun-Hee Kim³, Gyeong-Tae Gwak⁴

Affiliations

¹ Department of Physical Therapy, College of Health Science, Laboratory of KEMA AI Research (KAIR), Yonsei University, 234 Maeji-ri, Heungeop-Myeon, Wonju, Kangwon-Do, 220-710, South Korea. Electronic address: hwangu33@nate.com.
² Department of Physical Therapy, College of Health Science, Laboratory of Kinetic Ergocise Based on Movement Analysis, Yonsei University, 234 Maeji-ri, Heungeop-Myeon, Wonju, Kangwon-Do, 220-710, South Korea. Electronic address: kwonoy@yonsei.ac.kr.
³ Department of Physical Therapy, College of Health Science, Laboratory of KEMA AI Research (KAIR), Yonsei University, 234 Maeji-ri, Heungeop-Myeon, Wonju, Kangwon-Do, 220-710, South Korea. Electronic address: kemakjh@naver.com.
⁴ Department of Physical Therapy, College of Health Science, Laboratory of KEMA AI Research (KAIR), Yonsei University, 234 Maeji-ri, Heungeop-Myeon, Wonju, Kangwon-Do, 220-710, South Korea. Electronic address: tytyte@naver.com.

PMID: 39579676
DOI: 10.1016/j.msksp.2024.103230

Abstract

Objective: Chronic ankle instability (CAI) frequently develops as a result of lateral ankle sprains (LAS) in delivery service workers (DSWs). Identifying risk factors for CAI is crucial for implementing targeted interventions. This study aimed to develop machine learning (ML) models for classifying CAI in DSWs with a history of LAS (DSWsLAS) and to identify key contributory factors.

Design: Exploratory, cross-sectional design.

Setting: and participants: A total of 121 DSWsLAS were screened for eligibility among 289 DSWs.

Methods: A total of 121 DSWsLAS were assessed for demographic characteristics, including ankle strength, range of motion, postural control, and anatomical deformities. Seven ML algorithms were trained and tested for classifying CAI. Principal component analysis (PCA) was used for feature extraction, and feature permutation importance (FPI) and Shapley additive explanations (SHAP) were employed to identify influential features.

Main outcome measures: Model performances were assessed using area under the curve (AUC). To interpret the classifications, we used FPI and SHAP values.

Results: PCA derived 7 principal components (PCs) accounting for 83.5% of the total variation in the data. The support vector machine (SVM) algorithm achieved the highest classifying performance (AUC = 0.817) among the ML models. FPI and SHAP revealed that PC1, PC2, PC5, and PC7 were the most influential features for classifying CAI in DSWsLAS.

Conclusions: The SVM algorithm, utilizing PCA-derived factors related to body mass index and ankle muscle strength demonstrated high classifying performance for diagnosis of CAI in DSWsLAS, emphasizing the importance of considering multiple contributory factors in the prevention and management of this condition.

Keywords: Ankle sprain; Ergonomics; Joint instability; Occupational health.