Finding brain oscillations with power dependencies in neuroimaging data

Phase synchronization among neuronal oscillations within the same frequency band has been hypothesized to be a major mechanism for communication between different brain areas. On the other hand, cross-frequency communications are more flexible allowing interactions between oscillations with differen...

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Bibliographic Details
Published in:NeuroImage (Orlando, Fla.) Fla.), 2014-08, Vol.96, p.334-348
Main Authors: Dähne, Sven, Nikulin, Vadim V., Ramírez, David, Schreier, Peter J., Müller, Klaus-Robert, Haufe, Stefan
Format: Article
Language:English
Subjects:
Algorithms
Biological Clocks - physiology
Brain
Brain - physiology
Brain Mapping - methods
Brain research
Brain Waves - physiology
Classification
Correlation analysis
Cross-frequency coupling
cSPoC
Data Interpretation, Statistical
ECoG
EEG
Frequency bands
Humans
Image Enhancement - methods
Image Interpretation, Computer-Assisted - methods
LFP
Magnetoencephalography - methods
MEG
Nerve Net - physiology
Neural oscillations
Noise
Oscillations
Oscillometry - methods
Power-to-power coupling
Recording
Reproducibility of Results
Sensitivity and Specificity
Signal Processing, Computer-Assisted
Simulation
SPoC
Studies
Synchronism
Synchronization
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Summary:Phase synchronization among neuronal oscillations within the same frequency band has been hypothesized to be a major mechanism for communication between different brain areas. On the other hand, cross-frequency communications are more flexible allowing interactions between oscillations with different frequencies. Among such cross-frequency interactions amplitude-to-amplitude interactions are of a special interest as they show how the strength of spatial synchronization in different neuronal populations relates to each other during a given task. While, previously, amplitude-to-amplitude correlations were studied primarily on the sensor level, we present a source separation approach using spatial filters which maximize the correlation between the envelopes of brain oscillations recorded with electro-/magnetoencephalography (EEG/MEG) or intracranial multichannel recordings. Our approach, which is called canonical source power correlation analysis (cSPoC), is thereby capable of extracting genuine brain oscillations solely based on their assumed coupling behavior even when the signal-to-noise ratio of the signals is low. In addition to using cSPoC for the analysis of cross-frequency interactions in the same subject, we show that it can also be utilized for studying amplitude dynamics of neuronal oscillations across subjects. We assess the performance of cSPoC in simulations as well as in three distinctively different analysis scenarios of real EEG data, each involving several subjects. In the simulations, cSPoC outperforms unsupervised state-of-the-art approaches. In the analysis of real EEG recordings, we demonstrate excellent unsupervised discovery of meaningful power-to-power couplings, within as well as across subjects and frequency bands. •We introduce cSPoC as a novel unsupervised source separation tool for neuroimaging.•cSPoC optimally extracts power-coupled brain oscillations from EEG/MEG/LFP recordings.•cSPoC outperforms state-of-the-art source separation methods in realistic simulations.•cSPoC discovers sources with meaningful power coupling in three EEG experiments.•Power correlations found by cSPoC are on par with those of supervised approaches.
ISSN:1053-8119
1095-9572
DOI:10.1016/j.neuroimage.2014.03.075