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03.12.2018 | Original Paper

Estimating EEG Source Dipole Orientation Based on Singular-value Decomposition for Connectivity Analysis

verfasst von: M. Rubega, M. Carboni, M. Seeber, D. Pascucci, S. Tourbier, G. Toscano, P. Van Mierlo, P. Hagmann, G. Plomp, S. Vulliemoz, C. M. Michel

Erschienen in: Brain Topography | Ausgabe 4/2019

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Abstract

In the last decade, the use of high-density electrode arrays for EEG recordings combined with the improvements of source reconstruction algorithms has allowed the investigation of brain networks dynamics at a sub-second scale. One powerful tool for investigating large-scale functional brain networks with EEG is time-varying effective connectivity applied to source signals obtained from electric source imaging. Due to computational and interpretation limitations, the brain is usually parcelled into a limited number of regions of interests (ROIs) before computing EEG connectivity. One specific need and still open problem is how to represent the time- and frequency-content carried by hundreds of dipoles with diverging orientation in each ROI with one unique representative time-series. The main aim of this paper is to provide a method to compute a signal that explains most of the variability of the data contained in each ROI before computing, for instance, time-varying connectivity. As the representative time-series for a ROI, we propose to use the first singular vector computed by a singular-value decomposition of all dipoles belonging to the same ROI. We applied this method to two real datasets (visual evoked potentials and epileptic spikes) and evaluated the time-course and the frequency content of the obtained signals. For each ROI, both the time-course and the frequency content of the proposed method reflected the expected time-course and the scalp-EEG frequency content, representing most of the variability of the sources (~ 80%) and improving connectivity results in comparison to other procedures used so far. We also confirm these results in a simulated dataset with a known ground truth.

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Titel: Estimating EEG Source Dipole Orientation Based on Singular-value Decomposition for Connectivity Analysis
verfasst von: M. Rubega
M. Carboni
M. Seeber
D. Pascucci
S. Tourbier
G. Toscano
P. Van Mierlo
P. Hagmann
G. Plomp
S. Vulliemoz
C. M. Michel
Publikationsdatum: 03.12.2018
Verlag: Springer US
Erschienen in: Brain Topography / Ausgabe 4/2019
Print ISSN: 0896-0267
Elektronische ISSN: 1573-6792
DOI: https://doi.org/10.1007/s10548-018-0691-2

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Estimating EEG Source Dipole Orientation Based on Singular-value Decomposition for Connectivity Analysis

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