Time-Varying Temporal Functional Modes: An instantaneous connectivity-based method that probes brain network reconfigurations while allowing for a shared anatomical infrastructure
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2020-10-28
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nl
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Abstract
The core cognitive neuroscientific aim is to determine how the brain gives rise to mental
function. The answers provided to this ontological question depend, in part, on predominant
methodology. Initial functional magnetic resonance imaging studies were mainly
segregationist, i.e., focused on mapping psychological functions to individual brain sites. The
modularity hypothesis underlying this approach, however, has been questioned since its
conception. Conversely, it is argued that probing the neural underpinnings of mental function
requires examination of interactions within and between integrated, spatially distributed
functional brain networks. This is for example accomplished using functional connectivity
methods, which examine co-variation of spatially distributed signals emitted from the brain.
Time-averaged estimations of functional connectivity are commonly obtained, which assumes
that the dependence structure between brain regions is constant over the course of an fMRI
scan. In the past decennia, a line of research aims to probe time-varying functional
connectivity changes of these networks, based on the premise that biologically meaningful
changes in inter-regional relations are expected to occur. Available time-varying functional
connectivity methods do not allow for spatial overlap, i.e., for functional networks to share a
common anatomical infrastructure. This is addressed in Smith et al. (2012), where a spatial
independent component analysis and a temporal decomposition are applied consecutively,
resulting in so-called "Temporal Functional Modes" (TFMs). Classical TFM analysis is
time-invariant, however, in the sense that the extent to which TFMs recruit specific spatial
components (e.g. canonical functional connectivity networks) is assumed to be constant. To
capture the time-varying nature of functional connectivity and simultaneously allow for spatial
overlap, we developed a novel, time-varying version of classical TFM (TV-TFM) analysis.
With this extension, we obtain moment-by-moment estimations of brain network
reconfigurations, i.e. of how statistically independent temporal processes (i.e. TFMs) recruit
statistically independent spatial components. Properties of the new model were explored by
means of data simulations. Proof of principle for this new method was obtained by application
to high temporal resolution fMRI data of participants performing a visuomotor association
task. It was shown that the brain network reconfigurations captured with the new method
closely followed the expectation based on the task design.
Keywords: time-varying functional connectivity, dynamic functional connectivity,
independent component analysis, temporal functional modes, spatial overlap
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Faculteit der Sociale Wetenschappen