Abstract
A number of studies have tried to exploit subtle phase differences in BOLD time series to resolve the order of sequential activation of brain regions, or more generally the ability of signal in one region to predict subsequent signal in another region. More recently, such lag-based measures have been applied to investigate directed functional connectivity, although this application has been controversial. We attempted to use large publicly available datasets (FCON 1000, ADHD 200, Human Connectome Project) to determine whether consistent spatial patterns of Granger Causality are observed in typical fMRI data. For BOLD datasets from 1,240 typically developing subjects ages 7–40, we measured Granger causality between time series for every pair of 7,266 spherical ROIs covering the gray matter and 264 seed ROIs at hubs of the brain’s functional network architecture. Granger causality estimates were strongly reproducible for connections in a test and replication sample (n=620 subjects for each group), as well as in data from a single subject scanned repeatedly, both during resting and passive video viewing. The same effect was even stronger in high temporal resolution fMRI data from the Human Connectome Project, and was observed independently in data collected during performance of 7 task paradigms. The spatial distribution of Granger causality reflected vascular anatomy with a progression from Granger causality sources, in Circle of Willis arterial inflow distributions, to sinks, near large venous vascular structures such as dural venous sinuses and at the periphery of the brain. Attempts to resolve BOLD phase differences with Granger causality should consider the possibility of reproducible vascular confounds, a problem that is independent of the known regional variability of the hemodynamic response.
Highlights
A topic of great interest in recent literature is the creation of a directional connectome based on functional connectivity MRI data. fcMRI is based on the observation that different brain regions show synchronized blood-oxygen-leveldependent (BOLD) time series that correspond with established functional neuroanatomy[1]
We evaluated whether similar results could be obtained from a much more tightly controlled dataset, consisting of 100 5-minute fMRI acquisitions from a single subject over 3 weeks
We demonstrate that BOLD Granger causality differences can be reproducibly measured in large samples of resting state fMRI data between brain regions
Summary
A topic of great interest in recent literature is the creation of a directional connectome based on functional connectivity MRI (fcMRI) data. fcMRI is based on the observation that different brain regions show synchronized blood-oxygen-leveldependent (BOLD) time series that correspond with established functional neuroanatomy[1]. A topic of great interest in recent literature is the creation of a directional connectome based on functional connectivity MRI (fcMRI) data. FcMRI is based on the observation that different brain regions show synchronized blood-oxygen-leveldependent (BOLD) time series that correspond with established functional neuroanatomy[1]. Recent work has established consistent relationships across large numbers of subjects that show a canonical organization of brain network architecture that reflects extensive prior work characterizing regional brain function[2,3,4]. Most of the attempts to characterize a whole-brain connectome have been correlational, modeling mutual relationships between brain regions rather than determining the extent to which the communication is preferentially unidirectional[2,3,5,6,7,8]. In task-free, or undirected cognition, it is possible that similar relationships persist
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