AI Article Synopsis
- Ongoing neural activity in the central nervous system (CNS) shows spontaneous fluctuations that can be observed through BOLD signals in fMRI and consistently appear in specific brain networks.
- Both fast oscillation dynamics and scalp potential fluctuations occur within a similar low-frequency range, leading to questions about their relationship.
- Using simultaneous fbEEG and fMRI, the study found that infra-slow fluctuations in scalp potentials correlate with specific BOLD signals in defined resting-state networks, suggesting that these potentials reflect underlying changes in neuronal activity levels.
Article Abstract
Ongoing neuronal activity in the CNS waxes and wanes continuously across widespread spatial and temporal scales. In the human brain, these spontaneous fluctuations are salient in blood oxygenation level-dependent (BOLD) signals and correlated within specific brain systems or "intrinsic-connectivity networks." In electrophysiological recordings, both the amplitude dynamics of fast (1-100 Hz) oscillations and the scalp potentials per se exhibit fluctuations in the same infra-slow (0.01-0.1 Hz) frequency range where the BOLD fluctuations are conspicuous. While several lines of evidence show that the BOLD fluctuations are correlated with fast-amplitude dynamics, it has remained unclear whether the infra-slow scalp potential fluctuations in full-band electroencephalography (fbEEG) are related to the resting-state BOLD signals. We used concurrent fbEEG and functional magnetic resonance imaging (fMRI) recordings to address the relationship of infra-slow fluctuations (ISFs) in scalp potentials and BOLD signals. We show here that independent components of fbEEG recordings are selectively correlated with subsets of cortical BOLD signals in specific task-positive and task-negative, fMRI-defined resting-state networks. This brain system-specific association indicates that infra-slow scalp potentials are directly associated with the endogenous fluctuations in neuronal activity levels. fbEEG thus yields a noninvasive, high-temporal resolution window into the dynamics of intrinsic connectivity networks. These results support the view that the slow potentials reflect changes in cortical excitability and shed light on neuronal substrates underlying both electrophysiological and behavioral ISFs.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC6608153 | PMC |
| http://dx.doi.org/10.1523/JNEUROSCI.0276-13.2014 | DOI Listing |
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