Self-expressive subspace clustering to recognize motion dynamics for chronic ankle instability

Ankle sprains and instability are major public health concerns. Up to 70% of individuals do not fully recover from single ankle sprains and eventually develop chronic ankle instability (CAI). The diagnosis of CAI has been mainly based on self-report rather than objective biomechanical measures. The...

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Bibliographic Details
Published inIISE transactions on healthcare systems engineering Vol. 10; no. 1; pp. 60 - 73
Main Authors Qian, Shaodi, Yen, Sheng-Che, Folmar, Eric, Chou, Chun-An
Format Journal Article
LanguageEnglish
Published Abingdon Taylor & Francis 02.01.2020
Taylor & Francis Ltd
Subjects
Ankle
Biomechanics
Central nervous system
Chronic ankle instability
Clustering
Coordinates
decision model
Diagnosis
Dynamic stability
Gait
gait data analysis
Joints (anatomy)
Motion stability
pattern recognition
Public health
Rehabilitation
subspace learning
Subspaces
Support vector machines
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Summary:Ankle sprains and instability are major public health concerns. Up to 70% of individuals do not fully recover from single ankle sprains and eventually develop chronic ankle instability (CAI). The diagnosis of CAI has been mainly based on self-report rather than objective biomechanical measures. The goal of this study is to quantitatively recognize the motion patterns of a multi-joint coordinate system using gait data of bilateral hip, knee, and ankle joints, and further distinguish CAI from control cohorts. We propose an analytic framework, where the concept of subspace clustering is applied to characterize the dynamic gait patterns in a lower dimensional subspace from an inter-dependent network of multiply joints. A support vector machine model is built to validate the learned measures compared to traditional statistical measures in a leave-one-subject-out cross validation. The experimental results showed >70% classification accuracy on average for the dataset of 47 subjects (24 with CAI and 23 controls) recruited to examine in our designed experiment. It is found that CAI can be observed from other joints (e.g., hips) significantly, which reflects the fact that there exists inter-dependency in the multi-joint coordinate system. The proposed framework presents a potential to support clinical decisions using quantitative measures during diagnosis, treatment, rehabilitation of gait abnormality caused by physical injuries (e.g., ankle sprains in this study) or even central nervous system disorders.
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ISSN:2472-5579
2472-5587
DOI:10.1080/24725579.2019.1673521