Predicting Multiple Sclerosis from Gait Dynamics
Using an Instrumented Treadmill – A Machine
Learning Approach

Rachneet Kaur, Zizhang Chen, Robert Motl, Manuel Hernandez, Richard Sowers
University of Illinois at Urbana-Champaign
IEEE Transactions on Biomedical Engineering (TBME), 2020

[Code]
[Slides]
[Video]
[Paper]

Abstract

Objective: Multiple Sclerosis (MS) is a neurological condition which widely affects people 50-60 years of age. While clinical presentations of MS are highly heterogeneous, mobility limitations are one of the most frequent symptoms. This study examines a machine learning (ML) framework for identifying MS through spatiotemporal and kinetic gait features.
Methods: In this study, gait data during self-paced walking on an instrumented treadmill from 20 persons with MS and 20 age, weight, height, and gender-matched healthy older adults (HOA) were obtained. We explored two strategies to normalize data and minimize dependence on subject demographics; size-normalization (standard body size-based normalization) and regress-normalization (regression-based normalization using scaling factors derived by regressing gait features on multiple subject demographics); and proposed an ML based methodology to classify individual strides of older persons with MS (PwMS) from healthy controls. We generalized both across different walking tasks and subjects.
Results: We observed that regress-normalization improved the accuracy of identifying pathological gait using ML when compared to size-normalization . When generalizing from comfortable walking to walking while talking, gradient boosting machine achieved the optimal subject classification accuracy and AUC of 94.3% and 1.0, respectively and for subject generalization, a multilayer perceptron resulted in the best accuracy and AUC of 80% and 0.86, respectively, both with regression-normalized data.
Conclusion: The integration of gait data and ML may provide a viable patient-centric approach to aid clinicians in monitoring MS.
Significance: The results of this study have future implications for the way regression normalized gait features may be clinically used to design ML-based disease prediction strategies and monitor disease progression in PwMS.

Figure: Filtered acceleration coordinates. Comparing 10 seconds of x, y, z-acceleration coordinates from the two accelerometers at hip (H) and knee (K) for a subject with low (A) and high (B) balance.


Explanatory video

A detailed video, corresponding slides: [Detailed slides].


References

Rachneet Kaur, Zizhang Chen, Robert Motl, Manuel Enrique Hernandez, Richard Sowers. Predicting Multiple Sclerosis from Gait Fynamics Using an Instrumented Treadmill – A Machine Learning Approach. In IEEE Transactions on Biomedical Engineering (TBME), 2020 [BibTex] [Text]


Acknowledgements

The authors would like to thank Gioella Chaparro and other members of the Mobility and Fall Prevention Research Lab for their assistance with data collection and the participants in this study for their contributions. RK is thankful to William Chittenden for the William A. Chittenden Award.

Website adapted from Jingxiang, Richard and Deepak.