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Abstract
BackgroundFunctional brain imaging studies have indicated that distinct anatomical brain regions can show coherent spontaneous neuronal activity during rest. Regions that show such correlated behavior are said to form resting-state networks (RSNs). RSNs have been investigated using seed-dependent functional connectivity maps and by using a number of model-free methods. However, examining RSNs across a group of subjects is still a complex task and often involves human input in selecting meaningful networks.Methodology/Principal FindingsWe report on a voxel based model-free normalized cut graph clustering approach with whole brain coverage for group analysis of resting-state data, in which the number of RSNs is computed as an optimal clustering fit of the data. Inter-voxel correlations of time-series are grouped at the individual level and the consistency of the resulting networks across subjects is clustered at the group level, defining the group RSNs. We scanned a group of 26 subjects at rest with a fast BOLD sensitive fMRI scanning protocol on a 3 Tesla MR scanner.Conclusions/SignificanceAn optimal group clustering fit revealed 7 RSNs. The 7 RSNs included motor/visual, auditory and attention networks and the frequently reported default mode network. The found RSNs showed large overlap with recently reported resting-state results and support the idea of the formation of spatially distinct RSNs during rest in the human brain.
Highlights
Functional brain imaging studies have suggested that the brain is not inactive during rest, but rather shows a default state of activation [1,2,3,4,5]
Resting-state fMRI patterns are traditionally examined by correlating the rest recorded fMRI timeseries of a single seed voxel against the time-series of all other voxels, resulting in a functional connectivity map
We report on a group clustering method to select resting-state networks at a group level
Summary
Functional brain imaging studies have suggested that the brain is not inactive during rest, but rather shows a default state of activation [1,2,3,4,5]. Low frequency oscillations (ranging from 0.01 to 0.1 Hz) of resting-state functional Magnetic Resonance Imaging (fMRI) time-series are known to show correlated patterns between anatomical separated brain regions [1,6,7]. These correlations are suggested to originate from coherency in the underlying neuronal activation patterns of these regions and believed to reflect functional connectivity. Functional brain imaging studies have indicated that distinct anatomical brain regions can show coherent spontaneous neuronal activity during rest Regions that show such correlated behavior are said to form resting-state networks (RSNs). Examining RSNs across a group of subjects is still a complex task and often involves human input in selecting meaningful networks
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