Abstract
Simultaneous EEG‐fMRI allows multiparametric characterisation of brain function, in principle enabling a more complete understanding of brain responses; unfortunately the hostile MRI environment severely reduces EEG data quality. Simply eliminating data segments containing gross motion artefacts [MAs] (generated by movement of the EEG system and head in the MRI scanner's static magnetic field) was previously believed sufficient. However recently the importance of removal of all MAs has been highlighted and new methods developed. A systematic comparison of the ability to remove MAs and retain underlying neuronal activity using different methods of MA detection and post‐processing algorithms is needed to guide the neuroscience community. Using a head phantom, we recorded MAs while simultaneously monitoring the motion using three different approaches: Reference Layer Artefact Subtraction (RLAS), Moiré Phase Tracker (MPT) markers and Wire Loop Motion Sensors (WLMS). These EEG recordings were combined with EEG responses to simple visual tasks acquired on a subject outside the MRI environment. MAs were then corrected using the motion information collected with each of the methods combined with different analysis pipelines. All tested methods retained the neuronal signal. However, often the MA was not removed sufficiently to allow accurate detection of the underlying neuronal signal. We show that the MA is best corrected using the RLAS combined with post‐processing using a multichannel, recursive least squares (M‐RLS) algorithm. This method needs to be developed further to enable practical utility; thus, WLMS combined with M‐RLS currently provides the best compromise between EEG data quality and practicalities of motion detection.
Highlights
Simultaneous EEG-fMRI is a multimodal technique that has been widely exploited in the 8 investigation of brain function
Data for this study were acquired in two stages: (i) the EEG MAs and data for all accompanying motion-monitoring methods were acquired on a head-shaped phantom in the MRI scanner; (ii) EEG data were acquired on a human subject outside the MRI environment to provide a gold standard recording of underlying neuronal activity
We have provided a quantitative comparison of the relative merits of different, previously proposed, methods for correcting motion artefacts induced in EEG data during simultaneous fMRI
Summary
Simultaneous EEG-fMRI is a multimodal technique that has been widely exploited in the 8 investigation of brain function. There are three main artefacts which are induced in the EEG data: 1) the gradient artefact (GA), caused by the switching of magnetic field gradients that are required in MRI (Yan, Mullinger et al.2009); 2) the pulse artefact (PA), related to the cardiac cycle and related pulsatile blood flow, thought to be induced by head motion and blood movement in the large static magnetic field of the MRI scanner (Yan, Mullinger et al 2010); 3) motion artefact (MA) caused by voluntary or involuntary head motion which results in the movement of the conductive paths of the EEG system and head in the static magnetic field (Jansen, White et al 2012). In addition to these effects other sources such as the helium pumps, ventilation, and lights can add additional noise into the EEG data acquired in the MRI environment (Mullinger, Brookes et al 2008), but these effects can usually be overcome by switching off these noise sources
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