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01-07-2018 | Original Paper

Large-Scale Traveling Waves in EEG Activity Following Eye Movement

Authors: Marcello Giannini, David M. Alexander, Andrey R. Nikolaev, Cees van Leeuwen

Published in: Brain Topography | Issue 4/2018

Abstract

In spontaneous, stimulus-evoked, and eye-movement evoked EEG, the oscillatory signal shows large scale, dynamically organized patterns of phase. We investigated eye-movement evoked patterns in free-viewing conditions. Participants viewed photographs of natural scenes in anticipation of a memory test. From 200 ms intervals following saccades, we estimated the EEG phase gradient over the entire scalp, and the wave activity, i.e. the goodness of fit of a wave model involving a phase gradient assumed to be smooth over the scalp. In frequencies centered at 6.5 Hz, large-scale phase organization occurred, peaking around 70 ms after fixation onset and taking the form of a traveling wave. According to the wave gradient, most of the times the wave spreads from the posterior-inferior to anterior–superior direction. In these directions, the gradients depended on the size and direction of the saccade. Wave propagation velocity decreased in the course of the fixation, particularly in the interval from 50 to 150 ms after fixation onset. This interval corresponds to the fixation-related lambda activity, which reflects early perceptual processes following fixation onset. We conclude that lambda activity has a prominent traveling wave component. This component consists of a short-term whole-head phase pattern of specific direction and velocity, which may reflect feedforward propagation of visual information at fixation.

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The choice of bin sizes (three bins of the same size and the last bin of the larger size) resembles the one adopted by Dandekar et al. (2012), but was adjusted to accommodate the larger saccade size in free viewing of photos of natural scenes.

In addition, we tested the dependency of the phase gradients on saccade directions. A repeated-measures ANOVA with factor Saccade Direction (4 levels: up, down, right, left) on the trial-averaged phase gradients in the same time window as for Saccade Size revealed effects for the Anterior-Posterior gradients (F(3, 51) = 9.3, p < 0.001, Huynh-Feldt ε = 0.91) and Inferior-Superior gradients (F(3, 51) = 5.7, p = 0.005, Huynh-Feldt ε = 0.73), but not for the Left–Right gradients (F(3, 51) = 0.2).

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Title: Large-Scale Traveling Waves in EEG Activity Following Eye Movement
Authors: Marcello Giannini
David M. Alexander
Andrey R. Nikolaev
Cees van Leeuwen
Publication date: 01-07-2018
Publisher: Springer US
Published in: Brain Topography / Issue 4/2018
Print ISSN: 0896-0267
Electronic ISSN: 1573-6792
DOI: https://doi.org/10.1007/s10548-018-0622-2

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Large-Scale Traveling Waves in EEG Activity Following Eye Movement

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