Automated assessment of foot elevation in adults with hereditary spastic paraplegia using inertial measurements and machine learning

Hereditary spastic paraplegias (HSPs) cause characteristic gait impairment leading to an increased risk of stumbling or even falling. Biomechanically, gait deficits are characterized by reduced ranges of motion in lower body joints, limiting foot clearance and ankle range of motion. To date, there i...

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Bibliographic Details
Published in:Orphanet journal of rare diseases 2023-08, Vol.18 (1), p.1-249, Article 249
Main Authors: Ollenschläger, Malte, Höfner, Patrick, Ullrich, Martin, Kluge, Felix, Greinwalder, Teresa, Loris, Evelyn, Regensburger, Martin, Eskofier, Bjoern M, Winkler, Jürgen, Gassner, Heiko
Format: Article
Language:English
Subjects:
Adults
Algorithms
Analysis
Ankle
Automation
Biomarkers
Biosensors
Care and treatment
Classification
Diagnosis
Disease
Feet
Gait
Gait analysis
Genetic aspects
Health aspects
Hereditary spastic paraplegia
Joints
Learning algorithms
Machine learning
Medical research
Methods
Motion capture
Movement disorders
Muscle spasticity
Paralysis
Paralysis, Spastic
Paresis
Patients
Quality of life
Range of motion
Rare diseases
Sensors
Spasticity
Technology application
Walking
Wearable sensors
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Summary:Hereditary spastic paraplegias (HSPs) cause characteristic gait impairment leading to an increased risk of stumbling or even falling. Biomechanically, gait deficits are characterized by reduced ranges of motion in lower body joints, limiting foot clearance and ankle range of motion. To date, there is no standardized approach to continuously and objectively track the degree of dysfunction in foot elevation since established clinical rating scales require an experienced investigator and are considered to be rather subjective. Therefore, digital disease-specific biomarkers for foot elevation are needed. This study investigated the performance of machine learning classifiers for the automated detection and classification of reduced foot dorsiflexion and clearance using wearable sensors. Wearable inertial sensors were used to record gait patterns of 50 patients during standardized 4 [formula omitted] 10 m walking tests at the hospital. Three movement disorder specialists independently annotated symptom severity. The majority vote of these annotations and the wearable sensor data were used to train and evaluate machine learning classifiers in a nested cross-validation scheme. The results showed that automated detection of reduced range of motion and foot clearance was possible with an accuracy of 87%. This accuracy is in the range of individual annotators, reaching an average accuracy of 88% compared to the ground truth majority vote. For classifying symptom severity, the algorithm reached an accuracy of 74%. Here, we show that the present wearable gait analysis system is able to objectively assess foot elevation patterns in HSP. Future studies will aim to improve the granularity for continuous tracking of disease severity and monitoring therapy response of HSP patients in a real-world environment.
ISSN:1750-1172
1750-1172
DOI:10.1186/s13023-023-02854-8