Quantitative Evaluation of Artifact Removal in Real Magnetoencephalogram Signals with Blind Source Separation

Escudero, Javier; Hornero, Roberto; Abásolo, Daniel; Fernández, Alberto

doi:10.1007/s10439-011-0312-7

Cited by 68 publications

(65 citation statements)

References 37 publications

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“…Filtering with a notch filter at 60 Hz was used to reduce the effects of line noise and it was followed by independent component analysis (ICA) to separate cerebral from non-cerebral activity using the extended Infomax algorithm as implemented in EEGLAB (Delorme and Makeig, 2004). The data were also whitened and reduced in dimensionality using principal component analysis with a threshold set to 95% of the total variance (Delorme and Makeig, 2004;Escudero et al, 2011;Antonakakis et al, 2013). The statistical values of kurtosis, Rényi entropy, and skewness of each independent component were used to eliminate ocular and cardiac artifacts.…”

Section: Data Preprocessingmentioning

confidence: 99%

“…The statistical values of kurtosis, Rényi entropy, and skewness of each independent component were used to eliminate ocular and cardiac artifacts. A component was considered an artifact if more than 20% of its values after normalization to zero mean and unit variance were outside the range [-2, +2] (Escudero et al, 2011;Dimitriadis et al, 2013a;Antonakakis et al, 2013Antonakakis et al, , 2015.…”

Section: Data Preprocessingmentioning

confidence: 99%

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Altered cross-frequency coupling in resting-state MEG after mild traumatic brain injury

Antonakakis

Dimitriadis

Zervakis

et al. 2016

International Journal of Psychophysiology

122

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Cross-frequency coupling (CFC) is thought to represent a basic mechanism of functional integration of neural networks across distant brain regions. In this study, we analyzed CFC profiles from resting state Magnetoencephalographic (MEG) recordings obtained from 30 mild traumatic brain injury (mTBI) patients and 50 controls. We used mutual information (MI) to quantify the phase-to-amplitude coupling (PAC) of activity among the recording sensors in six nonoverlapping frequency bands. After forming the CFC-based functional connectivity graphs, we employed a tensor representation and tensor subspace analysis to identify the optimal set of features for subject classification as mTBI or control. Our results showed that controls formed a dense network of stronger local and global connections indicating higher functional integration compared to mTBI patients.Furthermore, mTBI patients could be separated from controls with more than 90% classification accuracy. These findings indicate that analysis of brain networks computed from resting-state MEG with PAC and tensorial representation of connectivity profiles may provide a valuable biomarker for the diagnosis of mTBI.

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Section: Data Preprocessingmentioning

confidence: 99%

Section: Data Preprocessingmentioning

confidence: 99%

Altered cross-frequency coupling in resting-state MEG after mild traumatic brain injury

Antonakakis

Dimitriadis

Zervakis

et al. 2016

International Journal of Psychophysiology

122

View full text Add to dashboard Cite

show abstract

“…Independent component analysis (ICA), for example, is widely used to separate brain signals from noise and artifact components. Effective removal of noise and biological artifacts was reported in various publications (Dammers et al, 2010;Escudero et al, 2011;Mantini et al, 2008;Nikulin et al, 2011;Ting et al, 2006). Most of the proposed ICA based source separation methods are performed to identify and exclude artifacts from the recorded signal, while only a few studies have been performed to elicit brain responses from the decomposed signals (Dammers et al, 2010;Hild & Nagarajan, 2009;Nikulin et al, 2011).…”

Section: Introductionmentioning

confidence: 99%

“…Independent component analysis (ICA) is widely used to separate brain signals from artifact components using utilizing both semi-and fully automated procedures (Dammers et al, 2008;Escudero, et al, 2010Escudero, et al, , 2011Hironaga & Ioannides, 2007;Li, et al, 2006;Mantini et al, 2008;Ossadtchi et al, 2004;Ting et al, 2006). Independent component analysis was developed for solving the blind source separation (BSS) problem with the basic assumption, that the recorded data in a sensor array are linear sums of temporally independent components originating from spatially fixed sources (Bell & Sejnowski, 1995;Comon, 1994;Herault & Jutten, 1986;Hyvärinen, 1999).…”

mentioning

confidence: 99%

“…After signal decomposition the problem now is to objectively identify components of interest in such high dimensional data sets, as it is the case for modern MEG systems. Different strategies have been proposed to exactly tackle the problem of unsupervised component extraction to find either artifacts (Dammers et al, 2008;Escudero et al, 2011;Li et al, 2006;Mantini et al, 2008) or signal of interest (Dammers et al, 2010;Hild & Nagarajan, 2009;Nikulin et al, 2011;Vairavan et al, 2010). Apart from time series analysis applied to the independent components for the identification of the source of interest, it might be helpful to look at the so-called place map of each temporally independent component.…”

mentioning

confidence: 99%

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Detection of Artifacts and Brain Responses Using Instantaneous Phase Statistics in Independent Components

Dammers¹,

Schiek²

2011

Magnetoencephalography

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Removing Cardiac Artefacts in Magnetoencephalography with Resampled Moving Average Subtraction

2016

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Magnetoencephalography (MEG) signals are commonly contaminated by cardiac artefacts (CAs). Principle component analysis and independent component analysis have been widely used for removing CAs, but they typically require a complex procedure for the identification of CA-related components. We propose a simple and efficient method, resampled moving average subtraction (RMAS), to remove CAs from MEG data. Based on an electrocardiogram (ECG) channel, a template for each cardiac cycle was estimated by a weighted average of epochs of MEG data over consecutive cardiac cycles, combined with a resampling technique for accurate alignment of the time waveforms. The template was subtracted from the corresponding epoch of the MEG data. The resampling reduced distortions due to asynchrony between the cardiac cycle and the MEG sampling times. The RMAS method successfully suppressed CAs while preserving both event-related responses and high-frequency (>45 Hz) components in the MEG data.

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Quantitative Evaluation of Artifact Removal in Real Magnetoencephalogram Signals with Blind Source Separation

Cited by 68 publications

References 37 publications

Altered cross-frequency coupling in resting-state MEG after mild traumatic brain injury

Altered cross-frequency coupling in resting-state MEG after mild traumatic brain injury

Detection of Artifacts and Brain Responses Using Instantaneous Phase Statistics in Independent Components

Removing Cardiac Artefacts in Magnetoencephalography with Resampled Moving Average Subtraction

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