Interpretable Supervised Muscle Network Decomposition by Multifactorial ANOVA-ICA

Interpretable Supervised Muscle Network Decomposition by Multifactorial ANOVA-ICA

Functional muscular connectivity reflects the underlying muscle coordination and neural control strategies during motor or postural tasks. Dimensionality reduction techniques based on multivariate linear decomposition can identify the fundamental modes of variation from muscle network instances, and...

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Bibliographic Details
Main Author: Jun-Ichiro Hirayama
Format: Article
Language:English
Published: IEEE 2025-01-01
Series:IEEE Transactions on Neural Systems and Rehabilitation Engineering
Subjects:
Functional muscle network
independent component analysis
intermuscular coherence
supervised dimensionality reduction
surface electromyography
Online Access:https://ieeexplore.ieee.org/document/11025558/
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Summary:Functional muscular connectivity reflects the underlying muscle coordination and neural control strategies during motor or postural tasks. Dimensionality reduction techniques based on multivariate linear decomposition can identify the fundamental modes of variation from muscle network instances, and enable compact visualizations and human interpretation. Existing muscle network decomposition methods do not explicitly disentangle the influence of experimental factors such as task parameters or subject groups, hindering meaningful interpretation. To address this issue, a multifactorial supervised decomposition technique based on analysis of variance (ANOVA) is introduced and combined with independent component analysis (ICA) to enhance interpretability. The resulting ANOVA-ICA provides a framework for identifying interpretable modes of systematic variation in muscle networks, allowing each mode to be explicitly associated with individual task-/subject-related factors or their combinatorial effects as modeled by ANOVA. The proposed method is tested on intermuscular coherence networks obtained through surface electromyography for postural control during standing and longitudinal running training. Multifactorial ANOVA modeling and ICA both effectively improve the interpretability of the decomposition, relative to other baseline approaches. This study demonstrates the validity of our multifactorial supervised approach to muscle network decomposition, highlighting its potential for applications in areas such as motor neurophysiology and rehabilitation.
ISSN:1534-4320
1558-0210

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