Abstract
Accurate mapping of the functional interactions between remote brain areas with resting-state functional magnetic resonance imaging requires the quantification of their underlying dynamics. In conventional methodological pipelines, a spatial scale of interest is first selected and dynamic analysis then proceeds at this hypothesised level of complexity. If large-scale functional networks or states are studied, more local regional rearrangements are then not described, potentially missing important neurobiological information. Here, we propose a novel mathematical framework that jointly estimates resting-state functional networks and spatially more localised cross-regional modulations. To do so, the changes in activity of each brain region are modelled by a logistic regression including co-activation coefficients (reflective of network assignment, as they highlight simultaneous activations across areas) and causal interplays (denoting finer regional cross-talks, when one region active at time t modulates the t to t + 1 transition likelihood of another area). A two-parameter regularisation scheme is used to make these two sets of coefficients sparse: one controls overall sparsity, while the other governs the trade-off between co-activations and causal interplays, enabling to properly fit the data despite the yet unknown balance between both types of couplings. Across a range of simulation settings, we show that the framework successfully retrieves the two types of cross-regional interactions at once. Performance across noise and sample size settings was globally on par with that of other existing methods, with the potential to reveal more precise information missed by alternative approaches. Preliminary application to experimental data revealed that in the resting brain, co-activations and causal modulations co-exist with a varying balance across regions. Our methodological pipeline offers a conceptually elegant alternative for the assessment of functional brain dynamics and can be downloaded at https://c4science.ch/source/Sparse_logistic_regression.git.
Highlights
Introduction us criHow the brain is structurally wired at its most global spatial scale, and how information flows between remote processing centres, are essential questions to improve our mechanistic understanding of high-level behaviours [1]
When it comes to functional magnetic resonance imaging, the mapping of brain function is commonly performed from resting-state (RS) recordings through the computation of functional connectivity (FC), that is, the statistical interdependence between different time courses reflective of regional activity [2], as can be assessed from an array of measures [3]
One of the most notorious family of dynamic approaches simplifies the originally voxelwise functional magnetic resonance imaging (fMRI) data into a state-level representation: first, whole-brain FC is computed over successive temporal sub-windows, and the concatenated data across the full subject population at hand is decomposed into a set of dynamic FC
Summary
How the brain is structurally wired at its most global spatial scale, and how information flows between remote processing centres, are essential questions to improve our mechanistic understanding of high-level behaviours [1]. When it comes to functional magnetic resonance imaging (fMRI), the mapping of brain function is commonly performed from resting-state (RS) recordings through the computation of functional connectivity (FC), that is, the statistical interdependence between different time courses reflective of regional activity [2], as can be assessed from an array of measures [3]. Many methodological pipelines have been developed to dig into time-resolved FC, and map brain function dynamically (see [11, 12, 13, 14] for contemporary reviews).
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