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Characterizing Variability of Modular Brain Connectivity with Constrained Principal Component Analysis

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  • Jun-ichiro Hirayama
  • Aapo Hyvärinen
  • Vesa Kiviniemi
  • Motoaki Kawanabe
  • Okito Yamashita

Abstract

Characterizing the variability of resting-state functional brain connectivity across subjects and/or over time has recently attracted much attention. Principal component analysis (PCA) serves as a fundamental statistical technique for such analyses. However, performing PCA on high-dimensional connectivity matrices yields complicated “eigenconnectivity” patterns, for which systematic interpretation is a challenging issue. Here, we overcome this issue with a novel constrained PCA method for connectivity matrices by extending the idea of the previously proposed orthogonal connectivity factorization method. Our new method, modular connectivity factorization (MCF), explicitly introduces the modularity of brain networks as a parametric constraint on eigenconnectivity matrices. In particular, MCF analyzes the variability in both intra- and inter-module connectivities, simultaneously finding network modules in a principled, data-driven manner. The parametric constraint provides a compact module-based visualization scheme with which the result can be intuitively interpreted. We develop an optimization algorithm to solve the constrained PCA problem and validate our method in simulation studies and with a resting-state functional connectivity MRI dataset of 986 subjects. The results show that the proposed MCF method successfully reveals the underlying modular eigenconnectivity patterns in more general situations and is a promising alternative to existing methods.

Suggested Citation

  • Jun-ichiro Hirayama & Aapo Hyvärinen & Vesa Kiviniemi & Motoaki Kawanabe & Okito Yamashita, 2016. "Characterizing Variability of Modular Brain Connectivity with Constrained Principal Component Analysis," PLOS ONE, Public Library of Science, vol. 11(12), pages 1-24, December.
  • Handle: RePEc:plo:pone00:0168180
    DOI: 10.1371/journal.pone.0168180
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    Cited by:

    1. Ricardo Pio Monti & Alex Gibberd & Sandipan Roy & Matthew Nunes & Romy Lorenz & Robert Leech & Takeshi Ogawa & Motoaki Kawanabe & Aapo Hyvärinen, 2020. "Interpretable brain age prediction using linear latent variable models of functional connectivity," PLOS ONE, Public Library of Science, vol. 15(6), pages 1-25, June.

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