Abstract
Objective. The simultaneous application of electroencephalography (EEG) and functional magnetic resonance imaging (fMRI) opens up new ways to investigate the human brain. The EEG recordings of simultaneous EEG-fMRI, however, are overlaid to a great degree by fMRI related artifacts and an artifact reduction is mandatory before any EEG analysis. The most severe artifacts—the gradient artifact and the pulse artifact—are repetitive. Average artifact subtraction (AAS) technique exploits the repetitiveness and is presumably the most often used artifact reduction technique. In this method artifact templates are calculated by averaging over adjacent artifact epochs and subsequently the templates are subtracted to reduce the artifacts. Although the AAS technique is one of the best performing methods, artifact residuals are usually present in the resulting EEG after applying the AAS technique. This work aims at identifying sources of the artifact residuals. Approach. Application of the AAS technique to artificial EEG that is contaminated with artificial fMRI related artifacts. Main results. A new source of artifact residuals was identified. It was found that the AAS technique itself adds artifacts to the EEG during gradient artifact reduction, because the gradient artifact template is corrupted by pulse artifact remainders. Significance. This work shows that using a standard number of 25 epochs to calculate the gradient artifact template—as suggested by the inventors of AAS—results in substantial artifact residuals and consequently to a low EEG quality. Furthermore, the work discusses how potential solutions to this problem have serious side effects such as loss of adaptivity of the AAS technique. Hence, this problem must be considered carefully already in the design of simultaneous EEG-fMRI experiments.
Highlights
In recent years electroencephalography (EEG) and functional magnetic resonance imaging have been applied simultaneously to study the active human brain concurrently from electrophysiological and metabolic/cri pt vascular perspectives (Ritter2006, Mulert2010, Rosa2010, Huster2012)
Gonçalves et al proposed another modification: weighting epochs by their variance in the averaging step (Gonçalves2007). The idea behind this approach is that the artifact affected EEG epochs have a higher vari ance than those without artifacts. This method is possibly beneficial if single artifacts are present, but we identified the pulse artifact as the main contributor to the artifact residuals in the template
Our results reveal a previously unknown source of artifact residuals in EEG of simultaneous EEG-functional magnetic resonance imaging (fMRI)
Summary
In recent years electroencephalography (EEG) and functional magnetic resonance imaging (fMRI) have been applied simultaneously to study the active human brain concurrently from electrophysiological and metabolic/cri pt vascular perspectives (Ritter2006, Mulert2010, Rosa2010, Huster2012). FMRI in turn can be used to determine the locations of signal changes with high precision, but the time resolution is limited to seconds (Ogawa1990, Norris2006). By combining these two techniques, the information collected with one technique can be supplemented by information from the other (Rosa2010, Mullinger2011, Huster2012, Uludag2014). One example of such an application is the EEG-inus formed fMRI analysis technique that is used to localize epileptic centers in the brain prior to a brain surgery (Ives1993, Krakow1999, Rosenow2001, Laufs2012).
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