6533b85afe1ef96bd12b8c75
RESEARCH PRODUCT
Revealing the unique features of each individual's muscle activation signatures
Lilian LacourpailleFrançois HugFrançois HugFrançois HugSebastian LapuschkinFabian HorstJeroen Aelessubject
Movement patternsComputer science[SDV]Life Sciences [q-bio]MovementBiomedical EngineeringBiophysicsBioengineeringWalkingElectromyographyBiochemistryLower limbMachine LearningBiomaterials03 medical and health sciences0302 clinical medicine[SDV.MHEP.PHY]Life Sciences [q-bio]/Human health and pathology/Tissues and Organs [q-bio.TO]medicineHumansRelevance (information retrieval)Muscle SkeletalElectromyographic (EMG)030304 developmental biology0303 health sciencesmedicine.diagnostic_testElectromyographybusiness.industryMusclesMotor controlLife Sciences–Physics interfacePattern recognitionMuscle activationSignature (logic)Support vector machineStatistical classificationArtificial intelligencebusiness030217 neurology & neurosurgeryBiotechnologydescription
International audience; There is growing evidence that each individual has unique movement patterns, or signatures. The exact origin of these movement signatures, however, remains unknown. We developed an approach that can identify individual muscle activation signatures during two locomotor tasks (walking and pedalling). A linear support vector machine was used to classify 78 participants based on their electromyographic (EMG) patterns measured on eight lower limb muscles. To provide insight into decision-making by the machine learning classification model, a layer-wise relevance propagation (LRP) approach was implemented. This enabled the model predictions to be decomposed into relevance scores for each individual input value. In other words, it provided information regarding which features of the time-varying EMG profiles were unique to each individual. Through extensive testing, we have shown that the LRP results, and by extent the activation signatures, are highly consistent between conditions and across days. In addition, they are minimally influenced by the dataset used to train the model. Additionally, we proposed a method for visualizing each individual's muscle activation signature, which has several potential clinical and scientific applications. This is the first study to provide conclusive evidence of the existence of individual muscle activation signatures.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2021-01-01 | Journal of The Royal Society Interface |