Your search keyword '"Beamformer"' showing total 20 results

1. Localization of brain signals by alternating projection.

Author

Adler, Amir, Wax, Mati, and Pantazis, Dimitrios

Subjects

SIGNAL-to-noise ratio, SIGNALS & signaling, ELECTROENCEPHALOGRAPHY, MACHINE translating

Abstract

A popular approach for modeling brain activity in MEG and EEG is based on a small set of current dipoles, where each dipole represents the combined activation of a local area of the brain. Here, we address the problem of multiple dipole localization with a novel solution called Alternating Projection (AP). The AP solution is based on minimizing the least-squares (LS) criterion by transforming the multi-dimensional optimization required for direct LS solution, to a sequential and iterative solution in which one source at a time is localized, while keeping the other sources fixed. Results from simulated, phantom, and human MEG data demonstrated the high accuracy of the AP method, with superior localization results than popular scanning methods from the multiple-signal classification (MUSIC) and beamformer families. In addition, the AP method was more robust to forward model errors resulting from head rotations and translations, as well as different cortex tessellation grids for the forward and inverse solutions, with consistently higher localization accuracy in low SNR and highly correlated sources. • A novel solution to the problem of MEG and EEG brain signals localization. • A low-complexity iterative solution is presented, involving only 1-dimensional optimization. • Performance simulation in challenging signal-to-noise ratios and head modeling errors demonstrate the superiority of the proposed solution. • Experimental study with phantom data as well as somatosensory and auditory human data demonstrate the superiority of the proposed solution. [ABSTRACT FROM AUTHOR]

Published

2024

2. Validating EEG, MEG and Combined MEG and EEG Beamforming for an Estimation of the Epileptogenic Zone in Focal Cortical Dysplasia

Author

Frank Neugebauer, Marios Antonakakis, Kanjana Unnwongse, Yaroslav Parpaley, Jörg Wellmer, Stefan Rampp, and Carsten H. Wolters

Subjects

epilepsy, beamformer, MEG, EEG, regularization, validation, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

MEG and EEG source analysis is frequently used for the presurgical evaluation of pharmacoresistant epilepsy patients. The source localization of the epileptogenic zone depends, among other aspects, on the selected inverse and forward approaches and their respective parameter choices. In this validation study, we compare the standard dipole scanning method with two beamformer approaches for the inverse problem, and we investigate the influence of the covariance estimation method and the strength of regularization on the localization performance for EEG, MEG, and combined EEG and MEG. For forward modelling, we investigate the difference between calibrated six-compartment and standard three-compartment head modelling. In a retrospective study, two patients with focal epilepsy due to focal cortical dysplasia type IIb and seizure freedom following lesionectomy or radiofrequency-guided thermocoagulation (RFTC) used the distance of the localization of interictal epileptic spikes to the resection cavity resp. RFTC lesion as reference for good localization. We found that beamformer localization can be sensitive to the choice of the regularization parameter, which has to be individually optimized. Estimation of the covariance matrix with averaged spike data yielded more robust results across the modalities. MEG was the dominant modality and provided a good localization in one case, while it was EEG for the other. When combining the modalities, the good results of the dominant modality were mostly not spoiled by the weaker modality. For appropriate regularization parameter choices, the beamformer localized better than the standard dipole scan. Compared to the importance of an appropriate regularization, the sensitivity of the localization to the head modelling was smaller, due to similar skull conductivity modelling and the fixed source space without orientation constraint.

Published

2022

3. NUTMEG: Open Source Software for MEG/EEG Source Reconstruction

Author

Zumer, Johanna M., Wong, Daniel D. E., Guggisberg, Adrian G., Nagarajan, Srikantan S., Dalal, Sarang S., Supek, Selma, editor, and Aine, Cheryl J., editor

Published

2014

4. Cortical hemispheric asymmetries are present at young ages and further develop into adolescence.

Author

Yamazaki, Hiroshi, Easwar, Vijayalakshmi, Polonenko, Melissa Jane, Jiwani, Salima, Wong, Daniel D. E., Papsin, Blake Croll, and Gordon, Karen Ann

Abstract

Abstract: Specialization of the auditory cortices for pure tone listening may develop with age. In adults, the right hemisphere dominates when listening to pure tones and music; we thus hypothesized that (a) asymmetric function between auditory cortices increases with age and (b) this development is specific to tonal rather than broadband/non‐tonal stimuli. Cortical responses to tone‐bursts and broadband click‐trains were recorded by multichannel electroencephalography in young children (5.1 ± 0.8 years old) and adolescents (15.2 ± 1.7 years old) with normal hearing. Peak dipole moments indicating activity strength in right and left auditory cortices were calculated using the Time Restricted, Artefact and Coherence source Suppression (TRACS) beamformer. Monaural click‐trains and tone‐bursts in young children evoked a dominant response in the contralateral right cortex by left ear stimulation and, similarly, a contralateral left cortex response to click‐trains in the right ear. Responses to tone‐bursts in the right ear were more bilateral. In adolescents, peak activity dominated in the right cortex in most conditions (tone‐bursts from either ear and to clicks from the left ear). Bilateral activity was evoked by right ear click stimulation. Thus, right hemispheric specialization for monaural tonal stimuli begins in children as young as 5 years of age and becomes more prominent by adolescence. These changes were marked by consistent dipole moments in the right auditory cortex with age in contrast to decreases in dipole activity in all other stimulus conditions. Together, the findings reveal increasingly asymmetric function for the two auditory cortices, potentially to support greater cortical specialization with development into adolescence. [ABSTRACT FROM AUTHOR]

Published

2018

5. The Effect of Head Model Simplification on Beamformer Source Localization

Author

Frank Neugebauer, Gabriel Möddel, Stefan Rampp, Martin Burger, and Carsten H. Wolters

Subjects

EEG, MEG, source analysis, beamformer, realistic volume conductor modeling, finite element method, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Beamformers are a widely-used tool in brain analysis with magnetoencephalography (MEG) and electroencephalography (EEG). For the construction of the beamformer filters realistic head volume conductor modeling is necessary for accurately computing the EEG and MEG leadfields, i.e., for solving the EEG and MEG forward problem. In this work, we investigate the influence of including realistic head tissue compartments into a finite element method (FEM) model on the beamformer's localization ability. Specifically, we investigate the effect of including cerebrospinal fluid, gray matter, and white matter distinction, as well as segmenting the skull bone into compacta and spongiosa, and modeling white matter anisotropy. We simulate an interictal epileptic measurement with white sensor noise. Beamformer filters are constructed with unit gain, unit array gain, and unit noise gain constraint. Beamformer source positions are determined by evaluating power and excess sample kurtosis (g2) of the source-waveforms at all source space nodes. For both modalities, we see a strong effect of modeling the cerebrospinal fluid and white and gray matter. Depending on the source position, both effects can each be in the magnitude of centimeters, rendering their modeling necessary for successful localization. Precise skull modeling mainly effected the EEG up to a few millimeters, while both modalities could profit from modeling white matter anisotropy to a smaller extent of 5–10 mm. The unit noise gain or neural activity index beamformer behaves similarly to the array gain beamformer when noise strength is sufficiently high. Variance localization seems more robust against modeling errors than kurtosis.

Published

2017

6. The Effect of Head Model Simplification on Beamformer Source Localization.

Author

Neugebauer, Frank, Möddel, Gabriel, Rampp, Stefan, Burger, Martin, and Wolters, Carsten H.

Subjects

MAGNETOENCEPHALOGRAPHY, ELECTROENCEPHALOGRAPHY, BRAIN imaging

Abstract

Beamformers are a widely-used tool in brain analysis with magnetoencephalography (MEG) and electroencephalography (EEG). For the construction of the beamformer filters realistic head volume conductor modeling is necessary for accurately computing the EEG and MEG leadfields, i.e., for solving the EEG and MEG forward problem. In this work, we investigate the influence of including realistic head tissue compartments into a finite element method (FEM) model on the beamformer's localization ability. Specifically, we investigate the effect of including cerebrospinal fluid, gray matter, and white matter distinction, as well as segmenting the skull bone into compacta and spongiosa, and modeling white matter anisotropy. We simulate an interictal epileptic measurement with white sensor noise. Beamformer filters are constructed with unit gain, unit array gain, and unit noise gain constraint. Beamformer source positions are determined by evaluating power and excess sample kurtosis (g2) of the source-waveforms at all source space nodes. For both modalities, we see a strong effect of modeling the cerebrospinal fluid and white and gray matter. Depending on the source position, both effects can each be in the magnitude of centimeters, rendering their modeling necessary for successful localization. Precise skull modeling mainly effected the EEG up to a few millimeters, while both modalities could profit from modeling white matter anisotropy to a smaller extent of 5-10 mm. The unit noise gain or neural activity index beamformer behaves similarly to the array gain beamformer when noise strength is sufficiently high. Variance localization seems more robust against modeling errors than kurtosis. [ABSTRACT FROM AUTHOR]

Published

2017

7. Microsleeps are Associated with Stage-2 Sleep Spindles from Hippocampal-Temporal Network.

Author

Jonmohamadi, Yaqub, Poudel, Govinda R., Innes, Carrie C. R. H., and Jones, Richard D.

Subjects

*SLEEP spindles, *BIOLOGICAL neural networks, *ELECTROENCEPHALOGRAPHY, *INDEPENDENT component analysis, *SYNGNATHIDAE

Abstract

Behavioral microsleeps are associated with complete disruption of responsiveness for s to 15s. They can result in injury or death, especially in transport and military sectors. In this study, EEGs were obtained from five nonsleep-deprived healthy male subjects performing a 1h 2D tracking task. Microsleeps were detected in all subjects. Microsleep-related activities in the EEG were detected, characterized, separated from eye closure-related activity, and, via source-space-independent component analysis and power analysis, the associated sources were localized in the brain. Microsleeps were often, but not always, found to be associated with strong alpha-band spindles originating bilaterally from the anterior temporal gyri and hippocampi. Similarly, theta-related activity was identified as originating bilaterally from the frontal-orbital cortex. The alpha spindles were similar to sleep spindles in terms of frequency, duration, and amplitude-profile, indicating that microsleeps are equivalent to brief instances of Stage-2 sleep. [ABSTRACT FROM AUTHOR]

Published

2016

8. Task-positive and task-negative networks and their relation to depression: EEG beamformer analysis.

Author

Knyazev, Gennady G., Savostyanov, Alexander N., Bocharov, Andrey V., Tamozhnikov, Sergey S., and Saprigyn, Alexander E.

Subjects

*DIAGNOSIS of mental depression, *ELECTROENCEPHALOGRAPHY, *NEUROBIOLOGY, *FUNCTIONAL magnetic resonance imaging, *BEAMFORMING

Abstract

Major Depressive Disorder (MDD) has been associated with predominance of the default-mode network (DMN) over the task-positive network (TPN), which is considered a neurobiological base for ruminative responding. It is not known whether this predominance is a signature of the full-blown MDD or it already exists at preclinical stages. Besides, all relevant evidence has been obtained using fMRI, which allows for a precise spatial characterization of resting state networks (RSNs), but their neural correlates remain elusive. Here we show that after leakage correction of beamformer-projected resting EEG time series, seed-based oscillatory-power envelope correlation analysis allows revealing RSNs with significant similarity to respective fMRI RSNs. In a non-clinical sample, depressive symptoms, as measured by the Beck Depression Inventory, are associated with predominance of DMN over TPN connectivity in the right insula and the right temporal lobe in the delta frequency band. These findings imply that in individuals with heightened level of depressive symptoms, emotional circuits are stronger connected with DMN than TPN and should be more easily engaged in self-referential rumination than in responding to environmental challenges. The study’s findings are in agreement with fMRI evidence, thus confirming the neural base of the observed in fMRI research effects and showing that implicated in depression neural mechanism may already be in action even at preclinical stages. [ABSTRACT FROM AUTHOR]

Published

2016

9. ASMR amplifies low frequency and reduces high frequency oscillations

Author

Thomas R. Swart, Michael J. Banissy, Thomas P. Hein, Ricardo Bruña, Ernesto Pereda, and Joydeep Bhattacharya

Subjects

ASMR, Neuropsychology and Physiological Psychology, Cognitive Neuroscience, Source reconstruction, Emotions, Humans, Experimental and Cognitive Psychology, Electroencephalography, Beamformer, EEG, Anxiety, Meridians, Autonomous sensory meridian response

Abstract

Autonomous sensory meridian response (ASMR) describes an atypical multisensory experience of calming, tingling sensations in response to a specific subset of social audiovisual triggers. To date, the electrophysiological (EEG) correlates of ASMR remain largely unexplored. Here we sought to provide source-level signatures of oscillatory changes induced by this phenomenon and investigate potential decay effects—oscillatory changes in the absence of self-reported ASMR. We recorded brain activity using EEG as participants watched ASMR-inducing videos and self-reported changes in their state: no change (Baseline); enhanced relaxation (Relaxed); and ASMR sensations (ASMR). Statistical tests in the sensor-space were used to inform contrasts in the source-space, executed with beamformer reconstruction. ASMR modulated oscillatory power by decreasing high gamma (52–80 Hz) relative to Relaxed and by increasing alpha (8–13 Hz) and decreasing delta (1–4 Hz) relative to Baseline. At the source level, ASMR increased power in the low-mid frequency ranges (8–18 Hz) and decreased power in high frequency (21–80 Hz). ASMR decay effects reduced gamma (30–80 Hz) and in the source-space reduced high-beta/gamma power (21–80 Hz). The temporal profile of ASMR modulations in high-frequency power later shifts to lower frequencies (1–8 Hz), except for an enhanced alpha, which persists for up to 45 min post self-reported ASMR. Crucially, these results provide the first evidence that the cortical sources of ASMR tingling sensations may arise from decreases in higher frequency oscillations and that ASMR may induce a sustained relaxation state.

Published

2021

10. Source-space ICA for EEG source separation, localization, and time-course reconstruction.

Author

Jonmohamadi, Yaqub, Poudel, Govinda, Innes, Carrie, and Jones, Richard

Subjects

*ELECTROENCEPHALOGRAPHY, *INDEPENDENT component analysis, *BEAMFORMING, *PERFORMANCE evaluation, *VOXEL-based morphometry

Abstract

We propose source-space independent component analysis (ICA) for separation, tomography, and time-course reconstruction of EEG and MEG source signals. Source-space ICA is based on the application of singular value decomposition and ICA on the neuroelectrical signals from all brain voxels obtained post minimum-variance beamforming of sensor-space EEG or MEG. We describe the theoretical background and equations, then evaluate the performance of this technique in several different situations, including weak sources, bilateral correlated sources, multiple sources, and cluster sources. In this approach, tomographic maps of sources are obtained by back-projection of the ICA mixing coefficients into the source-space (3-D brain template). The advantages of source-space ICA over the popular alternative approaches of sensor-space ICA together with dipole fitting and power mapping via minimum-variance beamforming are demonstrated. Simulated EEG data were produced by forward head modeling to project the simulated sources onto scalp sensors, then superimposed on real EEG background. To illustrate the application of source-space ICA to real EEG source reconstruction, we show the localization and time-course reconstruction of visual evoked potentials. Source-space ICA is superior to the minimum-variance beamforming in the reconstruction of multiple weak and strong sources, as ICA allows weak sources to be identified and reconstructed in the presence of stronger sources. Source-space ICA is also superior to sensor-space ICA on accuracy of localization of sources, as source-space ICA applies ICA to the time-courses of voxels reconstructed from minimum-variance beamforming on a 3D scanning grid and these time-courses are optimally unmixed via the beamformer. Each component identified by source-space ICA has its own tomographic map which shows the extent to which each voxel has contributed to that component. [ABSTRACT FROM AUTHOR]

Published

2014

11. Comparison of beamformers for EEG source signal reconstruction.

Author

Jonmohamadi, Yaqub, Poudel, Govinda, Innes, Carrie, Weiss, Daniel, Krueger, Rejko, and Jones, Richard

Subjects

BEAMFORMING, ELECTROENCEPHALOGRAPHY, SIGNAL reconstruction, BRAIN function localization, MAGNETOCARDIOGRAPHY, BRAIN mapping, SIGNAL-to-noise ratio

Abstract

Recently, several new beamformers have been introduced for reconstruction and localization of neural sources from EEG and MEG. Although studies have compared the accuracy of beamformers for localization of strong sources in the brain, a comparison of new and conventional beamformers for time-course reconstruction of a desired source has not been previously undertaken. In this study, 8 beamformers were examined with respect to several parameters, including variations in depth, orientation, magnitude, and frequency of the simulated source to determine their (i) effectiveness at time-course reconstruction of the sources, and (ii) stability of their performances with respect to the input changes. The spatial and directional pass-bands of the beamformers were estimated via simulated and real EEG sources to determine spatial resolution. White-noise spatial maps of the beamformers were calculated to show which beamformers have a location bias. Simulated EEG data were produced by projection via forward head modelling of simulated sources onto scalp electrodes, then superimposed on real background EEG. Real EEG was recorded from a patient with essential tremor and deep brain implanted electrodes. Gain – the ratio of SNR of the reconstructed time-course to the input SNR – was the primary measure of performance of the beamformers. Overall, minimum-variance beamformers had higher Gains and superior spatial resolution to those of the minimum-norm beamformers, although their performance was more sensitive to changes in magnitude, depth, and frequency of the simulated source. White-noise spatial maps showed that several, but not all, beamformers have an undesirable location bias. [ABSTRACT FROM AUTHOR]

Published

2014

12. Localization of coherent sources by simultaneous MEG and EEG beamformer.

Author

Hong, Jun, Ahn, Minkyu, Kim, Kiwoong, and Jun, Sung

Subjects

*MAGNETOENCEPHALOGRAPHY, *ELECTROENCEPHALOGRAPHY, *COHERENCE (Optics), *BEAMFORMING, *ACOUSTIC stimulation, *PERFORMANCE evaluation

Abstract

Simultaneous magnetoencephalography (MEG) and electroencephalography (EEG) analysis is known generally to yield better localization performance than a single modality only. For simultaneous analysis, MEG and EEG data should be combined to maximize synergistic effects. Recently, beamformer for simultaneous MEG/EEG analysis was proposed to localize both radial and tangential components well, while single modality analyses could not detect them, or had relatively higher location bias. In practice, most interesting brain sources are likely to be activated coherently; however, conventional beamformer may not work properly for such coherent sources. To overcome this difficulty, a linearly constrained minimum variance (LCMV) beamformer may be used with a source suppression strategy. In this work, simultaneous MEG/EEG LCMV beamformer using source suppression was formulated firstly to investigate its capability over various suppression strategies. The localization performance of our proposed approach was examined mainly for coherent sources and compared thoroughly with the conventional simultaneous and single modality approaches, over various suppression strategies. For this purpose, we used numerous simulated data, as well as empirical auditory stimulation data. In addition, some strategic issues of simultaneous MEG/EEG analysis were discussed. Overall, we found that our simultaneous MEG/EEG LCMV beamformer using a source suppression strategy is greatly beneficial in localizing coherent sources. [ABSTRACT FROM AUTHOR]

Published

2013

13. Localization of cortico-peripheral coherence with electroencephalography

Author

Guggisberg, Adrian G., Dalal, Sarang S., Zumer, Johanna M., Wong, Daniel D., Dubovik, Sviatlana, Michel, Christoph M., and Schnider, Armin

Subjects

*ELECTROENCEPHALOGRAPHY, *MAGNETIC resonance imaging, *BRAIN physiology, *PATHOLOGY, *LOCALIZATION theory, *BEAMFORMING, *NUMERICAL calculations

Abstract

Abstract: Background: The analysis of coherent networks from continuous recordings of neural activity with functional MRI or magnetoencephalography has provided important new insights into brain physiology and pathology. Here we assess whether valid localizations of coherent cortical networks can also be obtained from high-resolution electroencephalography (EEG) recordings. Methods: EEG was recorded from healthy subjects and from patients with ischemic brain lesions during a tonic hand muscle contraction task and during continuous visual stimulation with an alternating checkerboard. These tasks induce oscillations in the primary hand motor area or in the primary visual cortex, respectively, which are coherent with extracerebral signals (hand muscle electromyogram or visual stimulation frequency). Cortical oscillations were reconstructed with different inverse solutions and the coherence between oscillations at each cortical voxel and the extracerebral signals was calculated. Moreover, simulations of coherent point sources were performed. Results: Cortico-muscular coherence was correctly localized to the primary hand motor area and the steady-state visual evoked potentials to the primary visual cortex in all subjects and patients. Sophisticated head models tended to yield better localization accuracy than a single sphere model. A Minimum Variance Beamformer (MVBF) provided more accurate and focal localizations of simulated point sources than an L2 Minimum Norm (MN) inverse solution. In the real datasets, the MN maps had less localization error but were less focal than MVBF maps. Conclusions: EEG can localize coherent cortical networks with sufficient accuracy. [Copyright &y& Elsevier]

Published

2011

14. Open Database of Epileptic EEG with MRI and Postoperational Assessment of Foci-a Real World Verification for the EEG Inverse Solutions.

Author

Zwoliński, Piotr, Roszkowski, Marcin, Żygierewicz, Jaroslaw, Haufe, Stefan, Nolte, Guido, and Durka, Piotr

Abstract

This paper introduces a freely accessible database , containing 23 datasets from patients diagnosed with and operated on for drug-resistant epilepsy. This was collected as part of the clinical routine at the Warsaw Memorial Child Hospital. Each record contains (1) pre-surgical electroencephalography (EEG) recording (10-20 system) with inter-ictal discharges marked separately by an expert, (2) a full set of magnetic resonance imaging (MRI) scans for calculations of the realistic forward models, (3) structural placement of the epileptogenic zone, recognized by electrocorticography (ECoG) and post-surgical results, plotted on pre-surgical MRI scans in transverse, sagittal and coronal projections, (4) brief clinical description of each case. The main goal of this project is evaluation of possible improvements of localization of epileptic foci from the surface EEG recordings. These datasets offer a unique possibility for evaluating different EEG inverse solutions. We present preliminary results from a subset of these cases, including comparison of different schemes for the EEG inverse solution and preprocessing. We report also a finding which relates to the selective parametrization of single waveforms by multivariate matching pursuit, which is used in the preprocessing for the inverse solutions. It seems to offer a possibility of tracing the spatial evolution of seizures in time. [ABSTRACT FROM AUTHOR]

Published

2010

15. EEG source analysis of chronic fatigue syndrome

Author

Flor-Henry, Pierre, Lind, John C., and Koles, Zoltan J.

Subjects

*CHRONIC fatigue syndrome, *RHEUMATOLOGISTS, *SPECTRAL analysis (Phonetics), *DISCRIMINANT analysis, *BRAIN mapping, *ELECTROENCEPHALOGRAPHY

Abstract

Abstract: Sixty-one dextral, unmedicated women with chronic fatigue syndrome (CFS) diagnosed according to the Fukuda criteria (1994) and referred for investigation by rheumatologists and internists were studied with quantitative EEG (43 channels) at rest with eyes open and during verbal and spatial cognitive activation. The EEGs from the patients were compared with recordings from 80 dextral healthy female controls. Only those subjects who could provide 20 1-s artefact-free segments of EEG were admitted into the study. The analysis consisted of the identification of the spatial patterns in the EEGs that maximally differentiated the two groups and the estimation of the cortical source distributions underlying these patterns. Spatial patterns were analyzed in the alpha (8–13Hz) and beta (14–20Hz) bands and the source distributions were estimated using the Borgiotti–Kaplan BEAMFORMER algorithm. The results indicate that the spatial patterns identified were effective in separating the two groups, providing a minimum correct retrospective classification rate of 72% in both frequency bands while the subjects were at rest to a maximum of 83% in the alpha band during the verbal cognitive condition. Underlying cortical source distributions showed significant differences between the two groups in both frequency bands and in all cognitive conditions. Lateralized cortical differences were evident between the two groups in the both frequency bands during both the verbal and spatial cognitive conditions. During these active cognitive conditions, the CFS group showed significantly greater source-current activity than the controls in the left frontal–temporal–parietal regions of the cortex. [Copyright &y& Elsevier]

Published

2010

16. Source localisation in concurrent EEG/fMRI: Applications at 7T

Author

Brookes, Matthew J., Vrba, Jiri, Mullinger, Karen J., Geirsdóttir, Gerða Björk, Yan, Winston X., Stevenson, Claire M., Bowtell, Richard, and Morris, Peter G.

Subjects

*BRAIN function localization, *MAGNETIC resonance imaging of the brain, *ELECTROENCEPHALOGRAPHY, *BEAMFORMING, *MEDIAN nerve

Abstract

Abstract: This paper investigates the application of source reconstruction methodologies to EEG data recorded in concurrent EEG/fMRI experiments at 7T. An EEG phantom containing a dipolar current source is described and used to investigate the accuracy of source localisation. Both dipole fitting and beamformer algorithms are shown to yield accurate locations for the dipole within the phantom. Source reconstruction methodologies are also shown to reduce significantly the level of interference in the recorded EEG, caused by the MR scanner. A comparison between beamformer and dipole fitting approaches is made and it is shown that, due to its adaptive weighting parameters, the beamformer provides better suppression of interference when compared to the dipole fit. In addition it is shown that, in the case of the beamformer, use of a high EEG channel density improves the level of interference reduction, and the ratio of measured signal to interference can be improved by a factor of ∼1.6 if the number of EEG electrodes is increased from 32 to 64. The interference reduction properties of source localisation are shown theoretically, in simulation, and in phantom data. Finally, in-vivo experiments conducted at 7T show that effects in the gamma band can be recorded using simultaneous EEG/fMRI. These results are achieved by application of beamformer methodology to 64 channel EEG data. [Copyright &y& Elsevier]

Published

2009

17. Validating EEG, MEG and Combined MEG and EEG Beamforming for an Estimation of the Epileptogenic Zone in Focal Cortical Dysplasia.

Author

Neugebauer, Frank, Antonakakis, Marios, Unnwongse, Kanjana, Parpaley, Yaroslav, Wellmer, Jörg, Rampp, Stefan, and Wolters, Carsten H.

Subjects

*ELECTROENCEPHALOGRAPHY, *BEAMFORMING, *FOCAL cortical dysplasia, *PARTIAL epilepsy, *REGULARIZATION parameter

Abstract

MEG and EEG source analysis is frequently used for the presurgical evaluation of pharmacoresistant epilepsy patients. The source localization of the epileptogenic zone depends, among other aspects, on the selected inverse and forward approaches and their respective parameter choices. In this validation study, we compare the standard dipole scanning method with two beamformer approaches for the inverse problem, and we investigate the influence of the covariance estimation method and the strength of regularization on the localization performance for EEG, MEG, and combined EEG and MEG. For forward modelling, we investigate the difference between calibrated six-compartment and standard three-compartment head modelling. In a retrospective study, two patients with focal epilepsy due to focal cortical dysplasia type IIb and seizure freedom following lesionectomy or radiofrequency-guided thermocoagulation (RFTC) used the distance of the localization of interictal epileptic spikes to the resection cavity resp. RFTC lesion as reference for good localization. We found that beamformer localization can be sensitive to the choice of the regularization parameter, which has to be individually optimized. Estimation of the covariance matrix with averaged spike data yielded more robust results across the modalities. MEG was the dominant modality and provided a good localization in one case, while it was EEG for the other. When combining the modalities, the good results of the dominant modality were mostly not spoiled by the weaker modality. For appropriate regularization parameter choices, the beamformer localized better than the standard dipole scan. Compared to the importance of an appropriate regularization, the sensitivity of the localization to the head modelling was smaller, due to similar skull conductivity modelling and the fixed source space without orientation constraint. [ABSTRACT FROM AUTHOR]

Published

2022

18. Source-space ICA for EEG source separation, localization, and time-course reconstruction

Author

Govinda Poudel, Yaqub Jonmohamadi, Carrie R. H. Innes, and Richard D. Jones

Subjects

Adult, Beamforming, Time Factors, time-course reconstruction, Cognitive Neuroscience, Electroencephalography, Space (mathematics), computer.software_genre, localization, Voxel, Singular value decomposition, Source separation, medicine, Humans, Computer Simulation, EEG, Mathematics, medicine.diagnostic_test, business.industry, Signal Processing, Computer-Assisted, Pattern recognition, Independent component analysis, Neurology, independent component analysis, Data Interpretation, Statistical, beamformer, Evoked Potentials, Visual, Tomography, Artificial intelligence, business, computer

Abstract

We propose source-space independent component analysis (ICA) for separation, tomography, and time-course reconstruction of EEG and MEG source signals. Source-space ICA is based on the application of singular value decomposition and ICA on the neuroelectrical signals from all brain voxels obtained post minimum-variance beamforming of sensor-space EEG or MEG. We describe the theoretical background and equations, then evaluate the performance of this technique in several different situations, including weak sources, bilateral correlated sources, multiple sources, and cluster sources. In this approach, tomographic maps of sources are obtained by back-projection of the ICA mixing coefficients into the source-space (3-D brain template). The advantages of source-space ICA over the popular alternative approaches of sensor-space ICA together with dipole fitting and power mapping via minimum-variance beamforming are demonstrated. Simulated EEG data were produced by forward head modeling to project the simulated sources onto scalp sensors, then superimposed on real EEG background. To illustrate the application of source-space ICA to real EEG source reconstruction, we show the localization and time-course reconstruction of visual evoked potentials. Source-space ICA is superior to the minimum-variance beamforming in the reconstruction of multiple weak and strong sources, as ICA allows weak sources to be identified and reconstructed in the presence of stronger sources. Source-space ICA is also superior to sensor-space ICA on accuracy of localization of sources, as source-space ICA applies ICA to the time-courses of voxels reconstructed from minimum-variance beamforming on a 3D scanning grid and these time-courses are optimally unmixed via the beamformer. Each component identified by source-space ICA has its own tomographic map which shows the extent to which each voxel has contributed to that component.

Published

2014

19. Microsleeps are associated with stage-2 sleep spindles from hippocampal-temporal network

Author

Richard D. Jones, Yaqub Jonmohamadi, Govinda Poudel, and Carrie R. H. Innes

Subjects

Adult, Male, Sleep Wake Disorders, Visual perception, Time Factors, temporal lobes, Microsleep, Computer Networks and Communications, Sleep spindle, Electroencephalography, Hippocampal formation, Neuropsychological Tests, Hippocampus, 050105 experimental psychology, localization, Temporal lobe, Fingers, 03 medical and health sciences, 0302 clinical medicine, Cortex (anatomy), Neural Pathways, medicine, Humans, 0501 psychology and cognitive sciences, EEG, ICA, Theta Rhythm, medicine.diagnostic_test, 05 social sciences, hippocampi, Signal Processing, Computer-Assisted, General Medicine, Beamformer, Temporal Lobe, sleep spindles, Alpha Rhythm, medicine.anatomical_structure, microsleeps, Visual Perception, Psychology, Sleep, Neuroscience, 030217 neurology & neurosurgery, Psychomotor Performance

Abstract

Behavioral microsleeps are associated with complete disruption of responsiveness for [Formula: see text][Formula: see text]s to 15[Formula: see text]s. They can result in injury or death, especially in transport and military sectors. In this study, EEGs were obtained from five nonsleep-deprived healthy male subjects performing a 1[Formula: see text]h 2D tracking task. Microsleeps were detected in all subjects. Microsleep-related activities in the EEG were detected, characterized, separated from eye closure-related activity, and, via source-space-independent component analysis and power analysis, the associated sources were localized in the brain. Microsleeps were often, but not always, found to be associated with strong alpha-band spindles originating bilaterally from the anterior temporal gyri and hippocampi. Similarly, theta-related activity was identified as originating bilaterally from the frontal-orbital cortex. The alpha spindles were similar to sleep spindles in terms of frequency, duration, and amplitude-profile, indicating that microsleeps are equivalent to brief instances of Stage-2 sleep.

Published

2016

20. Open Database of Epileptic EEG with MRI and Postoperational Assessment of Foci—a Real World Verification for the EEG Inverse Solutions

Author

Guido Nolte, Jarosław Żygierewicz, Piotr Zwoliński, Piotr J. Durka, Marcin Roszkowski, Stefan Haufe, and Publica

Subjects

Male, Neuroscience(all), 0206 medical engineering, 02 engineering and technology, Electroencephalography, computer.software_genre, Article, MUSIC, 03 medical and health sciences, Epilepsy, 0302 clinical medicine, medicine, Preprocessor, Humans, Epilepsy surgery, EEG, Postoperative Period, Electrocorticography, Brain Mapping, medicine.diagnostic_test, Database, MMP, Information Dissemination, General Neuroscience, Magnetic resonance imaging, Signal Processing, Computer-Assisted, Beamformer, medicine.disease, 020601 biomedical engineering, Matching pursuit, Magnetic Resonance Imaging, Sagittal plane, medicine.anatomical_structure, Database Management Systems, Female, Psychology, SVD, computer, 030217 neurology & neurosurgery, Software, MRI, Information Systems

Abstract

This paper introduces a freely accessible database http://eeg.pl/epi , containing 23 datasets from patients diagnosed with and operated on for drug-resistant epilepsy. This was collected as part of the clinical routine at the Warsaw Memorial Child Hospital. Each record contains (1) pre-surgical electroencephalography (EEG) recording (10-20 system) with inter-ictal discharges marked separately by an expert, (2) a full set of magnetic resonance imaging (MRI) scans for calculations of the realistic forward models, (3) structural placement of the epileptogenic zone, recognized by electrocorticography (ECoG) and post-surgical results, plotted on pre-surgical MRI scans in transverse, sagittal and coronal projections, (4) brief clinical description of each case. The main goal of this project is evaluation of possible improvements of localization of epileptic foci from the surface EEG recordings. These datasets offer a unique possibility for evaluating different EEG inverse solutions. We present preliminary results from a subset of these cases, including comparison of different schemes for the EEG inverse solution and preprocessing. We report also a finding which relates to the selective parametrization of single waveforms by multivariate matching pursuit, which is used in the preprocessing for the inverse solutions. It seems to offer a possibility of tracing the spatial evolution of seizures in time.