Classifying Lower Extremity Muscle Fatigue During Walking Using Machine Learning and Inertial Sensors

Fatigue in lower extremity musculature is associated with decline in postural stability, motor performance and alters normal walking patterns in human subjects. Automated recognition of lower extremity muscle fatigue condition may be advantageous in early detection of fall and injury risks. Supervis...

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Bibliographic Details
Published in:Annals of biomedical engineering 2014-03, Vol.42 (3), p.600-612
Main Authors: Zhang, Jian, Lockhart, Thurmon E., Soangra, Rahul
Format: Article
Language:English
Subjects:
Adolescent
Artificial Intelligence
Biochemistry
Biological and Medical Physics
Biomechanical Phenomena
Biomedical and Life Sciences
Biomedical Engineering and Bioengineering
Biomedicine
Biophysics
Classical Mechanics
Classification
Extremities
Fatigue
Fatigue (materials)
Female
Gait
Gait - physiology
Health risks
Humans
Inertial
Kernels
Lower Extremity - physiology
Male
Models, Biological
Muscle Fatigue - physiology
Muscle, Skeletal - physiology
Muscles
Support vector machines
Walking
Walking - physiology
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Summary:Fatigue in lower extremity musculature is associated with decline in postural stability, motor performance and alters normal walking patterns in human subjects. Automated recognition of lower extremity muscle fatigue condition may be advantageous in early detection of fall and injury risks. Supervised machine learning methods such as support vector machines (SVMs) have been previously used for classifying healthy and pathological gait patterns and also for separating old and young gait patterns. In this study we explore the classification potential of SVM in recognition of gait patterns utilizing an inertial measurement unit associated with lower extremity muscular fatigue. Both kinematic and kinetic gait patterns of 17 participants (29 ± 11 years) were recorded and analyzed in normal and fatigued state of walking. Lower extremities were fatigued by performance of a squatting exercise until the participants reached 60% of their baseline maximal voluntary exertion level. Feature selection methods were used to classify fatigue and no-fatigue conditions based on temporal and frequency information of the signals. Additionally, influences of three different kernel schemes (i.e., linear, polynomial, and radial basis function) were investigated for SVM classification. The results indicated that lower extremity muscle fatigue condition influenced gait and loading responses. In terms of the SVM classification results, an accuracy of 96% was reached in distinguishing the two gait patterns (fatigue and no-fatigue) within the same subject using the kinematic, time and frequency domain features. It is also found that linear kernel and RBF kernel were equally good to identify intra-individual fatigue characteristics. These results suggest that intra-subject fatigue classification using gait patterns from an inertial sensor holds considerable potential in identifying “at-risk” gait due to muscle fatigue.
ISSN:0090-6964
1573-9686
DOI:10.1007/s10439-013-0917-0