Abstract
Several methods have been applied to EEG or MEG signals to detect functional networks. In recent works using MEG/EEG and fMRI data, temporal ICA analysis has been used to extract spatial maps of resting-state networks with or without an atlas-based parcellation of the cortex. Since the links between the fMRI signal and the electromagnetic signals are not fully established, and to avoid any bias, we examined whether EEG alone was able to derive the spatial distribution and temporal characteristics of functional networks. To do so, we propose a two-step original method: 1) An individual multi-frequency data analysis including EEG-based source localisation and spatial independent component analysis, which allowed us to characterize the resting-state networks. 2) A group-level analysis involving a hierarchical clustering procedure to identify reproducible large-scale networks across the population. Compared with large-scale resting-state networks obtained with fMRI, the proposed EEG-based analysis revealed smaller independent networks thanks to the high temporal resolution of EEG, hence hierarchical organization of networks. The comparison showed a substantial overlap between EEG and fMRI networks in motor, premotor, sensory, frontal, and parietal areas. However, there were mismatches between EEG-based and fMRI-based networks in temporal areas, presumably resulting from a poor sensitivity of fMRI in these regions or artefacts in the EEG signals. The proposed method opens the way for studying the high temporal dynamics of networks at the source level thanks to the high temporal resolution of EEG. It would then become possible to study detailed measures of the dynamics of connectivity.
Highlights
The functional organisation of the brain follows two complementary principles known as functional segregation and functional integration [1,2]
Can resting-state networks (RSN) be spatially characterized in EEG alone at the individual level with a good reliability? Are these networks reproducible at the group level? What is the added value of the high temporal resolution of EEG? And how do the identified networks compare with functional MRI (fMRI) findings? In this paper we examine the potential of EEG alone to derive the spatial distribution and the temporal characteristics of large-scale resting-state functional networks
The associated transfer function was a correlation between the power of the reconstructed cortical sources of the EEG signal convolved with a hemodynamic response function (HRF) and the fMRI blood oxygen level-dependent (BOLD) signal [26] (Eq 1): PEEG HRF 1⁄4 Xf MRI ; ð1Þ
Summary
The functional organisation of the brain follows two complementary principles known as functional segregation and functional integration [1,2]. The principle of functional segregation asserts that populations of neurons, strongly interconnected (cortical surface area less than 1 cm2), work synchronously and form cerebral functional areas clearly delineated spatially, which may be associated with a specific elementary task [3]. For processing a high-level task, PLOS ONE | DOI:10.1371/journal.pone.0146845. MRI data are in Analyze format readable by all MRI processing tools For processing a high-level task, PLOS ONE | DOI:10.1371/journal.pone.0146845 January 19, 2016
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