ICA-based artifact correction improves spatial localization of adaptive spatial filters in MEG

Beamformers are one of the most common inverse models currently used in the estimation of source activity from magnetoencephelography (MEG) data. They rely on a minimization of total power while constraining the gain in the voxel of interest, resulting in the suppression of background noise. Nonetheless, in cases where background noise is strong compared to the source of interest, or when many sources are present, the ability of the beamformer to detect and accurately localize weak sources is reduced. In visual paradigms, two main background sources can substantially impact an accurate estimation of weaker sources. Ocular artifacts are orders of magnitude higher than neural sources making it difficult for the beamformer to effectively suppress them. Primary visual activations also result in strong signals that can impede localization of weak sources. In this paper, we systematically evaluated how neural (visual) and non-neural (eye, heart) sources affect the localization accuracy of frontal and medial temporal sources in visual tasks. These sources are of tremendous interest in learning and memory studies as well as in clinical settings (Alzheimer's/epilepsy) and are typically difficult to localize robustly in MEG. Empirical data from two tasks - active learning and control - were used to evaluate our analysis techniques. Global field power calculations showed multiple time periods where active learning was significantly different from response selection with dominant sources converging to the eyes. Extensive leakage of eye activity into frontal and visual that evoked responses into parietal cortices was also observed. Contributions from ocular activity to the reconstructed time series were indiscernible from task-based recruitment of frontal sources in the original data. Removing artifacts (eye movements, cardiac, and muscular) by means of independent component analysis (ICA) led to a significant improvement in detection and localization of frontal and medial temporal sources. We verified our results by using simulations of sources placed in frontal and medial temporal regions with various types of background noise (eye, heart, and visual). We report that the detection and localization accuracy of frontal and medial temporal sources with beamformer techniques is highly dependent on the magnitude and location of background sources and that removing artifacts can substantially improve the beamformer's performance.

[1]  Joachim Gross,et al.  Good practice for conducting and reporting MEG research , 2013, NeuroImage.

[2]  Lily Riggs,et al.  A complementary analytic approach to examining medial temporal lobe sources using magnetoencephalography , 2009, NeuroImage.

[3]  関原 謙介,et al.  Adaptive Spatial Filters for Electromagnetic Brain Imaging , 2008 .

[4]  R. Ilmoniemi,et al.  Magnetoencephalography-theory, instrumentation, and applications to noninvasive studies of the working human brain , 1993 .

[5]  Mark W. Woolrich,et al.  Inferring task-related networks using independent component analysis in magnetoencephalography , 2012, NeuroImage.

[6]  Sandra N. Moses,et al.  Techniques for Detection and Localization of Weak Hippocampal and Medial Frontal Sources Using Beamformers in MEG , 2012, Brain Topography.

[7]  Elizabeth W. Pang,et al.  Event-related beamforming: A robust method for presurgical functional mapping using MEG , 2007, Clinical Neurophysiology.

[8]  R. Greenblatt,et al.  Local linear estimators for the bioelectromagnetic inverse problem , 2005, IEEE Transactions on Signal Processing.

[9]  J. V. Haxby,et al.  Spatial Pattern Analysis of Functional Brain Images Using Partial Least Squares , 1996, NeuroImage.

[10]  G. Barnes,et al.  Realistic spatial sampling for MEG beamformer images , 2004, Human brain mapping.

[11]  Mark W. Woolrich,et al.  MEG beamforming using Bayesian PCA for adaptive data covariance matrix regularization , 2011, NeuroImage.

[12]  D. Cheyne,et al.  Evaluation of multiple-sphere head models for MEG source localization , 2011, Physics in medicine and biology.

[13]  Shannon D. Blunt,et al.  Spatio–Temporal Reconstruction of Bilateral Auditory Steady-State Responses Using MEG Beamformers , 2008, IEEE Transactions on Biomedical Engineering.

[14]  Margot J. Taylor,et al.  Detection and localization of hippocampal activity using beamformers with MEG: A detailed investigation using simulations and empirical data , 2011, Human brain mapping.

[15]  Douglas O. Cheyne,et al.  Reconstruction of correlated brain activity with adaptive spatial filters in MEG , 2010, NeuroImage.

[16]  Anthony Randal McIntosh,et al.  Partial least squares analysis of neuroimaging data: applications and advances , 2004, NeuroImage.

[17]  A Tikhonov,et al.  Solution of Incorrectly Formulated Problems and the Regularization Method , 1963 .

[18]  A. R. McIntosh,et al.  Spatiotemporal analysis of event-related fMRI data using partial least squares , 2004, NeuroImage.

[19]  Kensuke Sekihara,et al.  Modified beamformers for coherent source region suppression , 2006, IEEE Transactions on Biomedical Engineering.

[20]  Robert Tibshirani,et al.  Bootstrap Methods for Standard Errors, Confidence Intervals, and Other Measures of Statistical Accuracy , 1986 .

[21]  Andreas K. Engel,et al.  The saccadic spike artifact in MEG , 2012, NeuroImage.

[22]  Wolfgang Skrandies,et al.  Global field power and topographic similarity , 2005, Brain Topography.

[23]  Matthew J. Brookes,et al.  Beamformer reconstruction of correlated sources using a modified source model , 2007, NeuroImage.

[24]  J. Schoffelen,et al.  Dissociated α-band modulations in the dorsal and ventral visual pathways in visuospatial attention and perception. , 2014, Cerebral cortex.

[25]  W. Drongelen,et al.  Localization of brain electrical activity via linearly constrained minimum variance spatial filtering , 1997, IEEE Transactions on Biomedical Engineering.

[26]  R D Pascual-Marqui,et al.  Standardized low-resolution brain electromagnetic tomography (sLORETA): technical details. , 2002, Methods and findings in experimental and clinical pharmacology.

[27]  T. Picton,et al.  Correlates of eye blinking as determined by synthetic aperture magnetometry , 2006, Clinical Neurophysiology.

[28]  E. Pang,et al.  Recognising upright and inverted faces: MEG source localisation , 2011, Brain Research.

[29]  David Poeppel,et al.  Reconstructing spatio-temporal activities of neural sources using an MEG vector beamformer technique , 2001, IEEE Transactions on Biomedical Engineering.

[30]  Arnaud Delorme,et al.  EEGLAB: an open source toolbox for analysis of single-trial EEG dynamics including independent component analysis , 2004, Journal of Neuroscience Methods.

[31]  D. Cheyne,et al.  Spatiotemporal mapping of cortical activity accompanying voluntary movements using an event‐related beamforming approach , 2006, Human brain mapping.

[32]  Elizabeth W. Pang,et al.  The Development of Face Recognition; Hippocampal and Frontal Lobe Contributions Determined with MEG , 2011, Brain Topography.

[33]  Wolfgang Skrandies,et al.  Data reduction of multichannel fields: Global field power and Principal Component Analysis , 2005, Brain Topography.

[34]  Kensuke Sekihara,et al.  Localization bias and spatial resolution of adaptive and non-adaptive spatial filters for MEG source reconstruction , 2005, NeuroImage.

[35]  Vincent L. Gracco,et al.  Speech-induced suppression of evoked auditory fields in children who stutter , 2011, NeuroImage.

[36]  Robinson Se,et al.  Localization of event-related activity by SAM(erf). , 2004 .

[37]  T. Yoshimoto,et al.  Recent Advances in Biomagnetism , 2007 .

[38]  Margot J. Taylor,et al.  Brain noise is task dependent and region specific. , 2010, Journal of neurophysiology.

[39]  Thomas Kailath,et al.  Performance analysis of the optimum beamformer in the presence of correlated sources and its behavior under spatial smoothing , 1987, IEEE Trans. Acoust. Speech Signal Process..

[40]  Matthew J. Brookes,et al.  Simultaneous EEG source localisation and artifact rejection during concurrent fMRI by means of spatial filtering , 2008, NeuroImage.

[41]  Natasa Kovacevic,et al.  Semantic information alters neural activation during transverse patterning performance , 2009, NeuroImage.