Dual-Core Beamformer for obtaining highly correlated neuronal networks in MEG

The "Dual-Core Beamformer" (DCBF) is a new lead-field based MEG inverse-modeling technique designed for localizing highly correlated networks from noisy MEG data. Conventional beamformer techniques are successful in localizing neuronal sources that are uncorrelated under poor signal-to-noise ratio (SNR) conditions. However, they fail to reconstruct multiple highly correlated sources. Though previously published dual-beamformer techniques can successfully localize multiple correlated sources, they are computationally expensive and impractical, requiring a priori information. The DCBF is able to automatically calculate optimal amplitude-weighting and dipole orientation for reconstruction, greatly reducing the computational cost of the dual-beamformer technique. Paired with a modified Powell algorithm, the DCBF can quickly identify multiple sets of correlated sources contributing to the MEG signal. Through computer simulations, we show that the DCBF quickly and accurately reconstructs source locations and their time-courses under widely varying SNR, degrees of correlation, and source strengths. Simulations also show that the DCBF identifies multiple simultaneously active correlated networks. Additionally, DCBF performance was tested using MEG data in humans. In an auditory task, the DCBF localized and reconstructed highly correlated left and right auditory responses. In a median-nerve stimulation task, the DCBF identified multiple meaningful networks of activation without any a priori information. Altogether, our results indicate that the DCBF is an effective and valuable tool for reconstructing correlated networks of neural activity from MEG recordings.

[1]  Gareth R. Barnes,et al.  Imaging the dynamics of the auditory steady-state evoked response , 2005, Neuroscience Letters.

[2]  S. Vanni,et al.  Foveal attention modulates responses to peripheral stimuli. , 2000, Journal of neurophysiology.

[3]  Anders M. Dale,et al.  Dynamic Statistical Parametric Neurotechnique Mapping: Combining fMRI and MEG for High-Resolution Imaging of Cortical Activity , 2000 .

[4]  R. Ilmoniemi,et al.  Interpreting magnetic fields of the brain: minimum norm estimates , 2006, Medical and Biological Engineering and Computing.

[5]  Richard M. Leahy,et al.  Identifying true cortical interactions in MEG using the nulling beamformer , 2010, NeuroImage.

[6]  Anders M. Dale,et al.  Cortical Surface-Based Analysis I. Segmentation and Surface Reconstruction , 1999, NeuroImage.

[7]  O. Jensen,et al.  Neuromagnetic localization of rhythmic activity in the human brain: a comparison of three methods , 2005, NeuroImage.

[8]  Se Robinson,et al.  Functional neuroimaging by Synthetic Aperture Magnetometry (SAM) , 1999 .

[9]  Jouko Lampinen,et al.  Bayesian analysis of the neuromagnetic inverse problem with ℓ p -norm priors , 2005, NeuroImage.

[10]  J. Vrba,et al.  Signal processing in magnetoencephalography. , 2001, Methods.

[11]  David Poeppel,et al.  Application of an MEG eigenspace beamformer to reconstructing spatio‐temporal activities of neural sources , 2002, Human brain mapping.

[12]  Valerie A. Carr,et al.  Spatiotemporal Dynamics of Modality-Specific and Supramodal Word Processing , 2003, Neuron.

[13]  C Pantev,et al.  Right hemispheric laterality of human 40 Hz auditory steady-state responses. , 2005, Cerebral cortex.

[14]  Zhi Ding,et al.  CMA beamforming for multipath correlated sources , 1997, 1997 IEEE International Conference on Acoustics, Speech, and Signal Processing.

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

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

[17]  Ole Jensen,et al.  Altered generation of spontaneous oscillations in Alzheimer's disease , 2005, NeuroImage.

[18]  C. Tesche,et al.  Evidence for somatosensory evoked responses in human temporal lobe , 2000, Neuroreport.

[19]  David Poeppel,et al.  Asymptotic SNR of scalar and vector minimum-variance beamformers for neuromagnetic source reconstruction , 2004, IEEE Transactions on Biomedical Engineering.

[20]  Samu Taulu,et al.  Signal Space Separation Algorithm and Its Application on Suppressing Artifacts Caused by Vagus Nerve Stimulation for Magnetoencephalography Recordings , 2009, Journal of clinical neurophysiology : official publication of the American Electroencephalographic Society.

[21]  Anders M. Dale,et al.  Vector-based spatial–temporal minimum L1-norm solution for MEG , 2006, NeuroImage.

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

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

[24]  Hong-Goo Kang,et al.  Optimum beamformer in correlated source environments. , 2006, The Journal of the Acoustical Society of America.

[25]  Richard M. Leahy,et al.  Linearly constrained MEG beamformers for MVAR modeling of cortical interactions , 2006, 3rd IEEE International Symposium on Biomedical Imaging: Nano to Macro, 2006..

[26]  S. Taulu,et al.  Spatiotemporal signal space separation method for rejecting nearby interference in MEG measurements , 2006, Physics in medicine and biology.

[27]  Friedemann Pulvermüller,et al.  Spatiotemporal dynamics of neural language processing: an MEG study using minimum-norm current estimates , 2003, NeuroImage.

[28]  Roland R. Lee,et al.  Temporal dynamics of ipsilateral and contralateral motor activity during voluntary finger movement , 2004, Human brain mapping.

[29]  E. Somersalo,et al.  Visualization of Magnetoencephalographic Data Using Minimum Current Estimates , 1999, NeuroImage.

[30]  David Poeppel,et al.  Performance of an MEG adaptive-beamformer technique in the presence of correlated neural activities: effects on signal intensity and time-course estimates , 2002, IEEE Transactions on Biomedical Engineering.

[31]  Nikos Makris,et al.  Automatically parcellating the human cerebral cortex. , 2004, Cerebral cortex.

[32]  Riitta Hari,et al.  Comparison of Minimum Current Estimate and Dipole Modeling in the Analysis of Simulated Activity in the Human Visual Cortices , 2002, NeuroImage.

[33]  S. Taulu,et al.  Suppression of Interference and Artifacts by the Signal Space Separation Method , 2003, Brain Topography.

[34]  J. Stephen,et al.  Sources on the anterior and posterior banks of the central sulcus identified from magnetic somatosensory evoked responses using Multi‐Start Spatio‐Temporal localization , 2000, Human brain mapping.

[35]  Li Cui,et al.  Evaluation of signal space separation via simulation , 2007, Medical & Biological Engineering & Computing.

[36]  Gregory A. Miller,et al.  A parietal–frontal network studied by somatosensory oddball MEG responses, and its cross-modal consistency , 2005, NeuroImage.

[37]  E. Halgren,et al.  Spatiotemporal mapping of brain activity by integration of multiple imaging modalities , 2001, Current Opinion in Neurobiology.

[38]  W. Drongelen,et al.  A spatial filtering technique to detect and localize multiple sources in the brain , 1996, Brain Topography.