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Static and dynamic fMRI-derived functional connectomes represent largely similar information

Andraž Matkovič, Alan Anticevic, John D. Murray, Grega Repovš

2023Network Neuroscience17 citationsDOIOpen Access PDF

Abstract

Functional connectivity (FC) of blood oxygen level-dependent (BOLD) fMRI time series can be estimated using methods that differ in sensitivity to the temporal order of time points (static vs. dynamic) and the number of regions considered in estimating a single edge (bivariate vs. multivariate). Previous research suggests that dynamic FC explains variability in FC fluctuations and behavior beyond static FC. Our aim was to systematically compare methods on both dimensions. We compared five FC methods: Pearson's/full correlation (static, bivariate), lagged correlation (dynamic, bivariate), partial correlation (static, multivariate), and multivariate AR model with and without self-connections (dynamic, multivariate). We compared these methods by (i) assessing similarities between FC matrices, (ii) by comparing node centrality measures, and (iii) by comparing the patterns of brain-behavior associations. Although FC estimates did not differ as a function of sensitivity to temporal order, we observed differences between the multivariate and bivariate FC methods. The dynamic FC estimates were highly correlated with the static FC estimates, especially when comparing group-level FC matrices. Similarly, there were high correlations between the patterns of brain-behavior associations obtained using the dynamic and static FC methods. We conclude that the dynamic FC estimates represent information largely similar to that of the static FC.

Topics & Concepts

Bivariate analysisMultivariate statisticsCorrelationMultivariate analysisDynamic functional connectivitySensitivity (control systems)MathematicsComputer scienceStatisticsResting state fMRIPsychologyNeuroscienceElectronic engineeringGeometryEngineeringFunctional Brain Connectivity StudiesMental Health Research TopicsHeart Rate Variability and Autonomic Control