Influence of tissue conductivity anisotropy on EEG/MEG field and return current computation in a realistic head model: A simulation and visualization study using high-resolution finite element modeling

Wolters, Carsten H.; Anwander, Alfred; Tricoche, Xavier; Weinstein, David M.; Koch, Martin; MacLeod, Robert S.

doi:10.1016/j.neuroimage.2005.10.014

Cited by 398 publications

(486 citation statements)

References 44 publications

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Section: Discussionmentioning

confidence: 99%

“…following transcranial direct current stimulation) along trajectories parallel to the primary direction of the fiber tracts [4,27]. Sources located deep in the brain, as well as those bordering strongly anisotropic tissue, are misrepresented in EEG localization when neglecting the effects of white matter anisotropy [4]. One recent study that included an inverse analysis found that sulcal sources localized in EEG studies may be mislocalized outside of the sulci if white matter anisotropy is neglected [6].…”

Section: Discussionmentioning

confidence: 99%

“…In this paper we focus on the forward problem, which has not been given a great deal of attention in neuroimaging. Despite many published studies demonstrating high-quality head models and forward modeling approaches [2,3,4,5,6,7,8], most functional neuroimaging studies still rely on relatively poor quality electromagnetic head models when performing source localization.…”

Section: Introductionmentioning

confidence: 99%

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A finite-element reciprocity solution for EEG forward modeling with realistic individual head models

et al. 2014

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We present a finite element modeling (FEM) implementation for solving the forward problem in electroencephalography (EEG). The solution is based on Helmholtz's principle of reciprocity which allows for dramatically reduced computational time when constructing the leadfield matrix. The approach was validated using a 4-shell spherical model and shown to perform comparably with two current state-of-the-art alternatives (OpenMEEG for boundary element modeling and SimBio for finite element modeling).We applied the method to real human brain MRI data and created a model with five tissue types: white matter, grey matter, cerebrospinal fluid, skull, and scalp. By calculating conductivity tensors from diffusion-weighted MR images, we also demonstrate one of the main benefits of FEM: the ability to include anisotropic conductivities within the head model. Root-mean square deviation between the standard leadfield and the leadfield including white-matter anisotropy showed that ignoring the directional conductivity of white matter fiber tracts leads to orientation-specific errors in the forward model. Realistic head models are necessary for precise source localization in individuals. Our approach is fast, accurate, open-source and freely available online.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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A finite-element reciprocity solution for EEG forward modeling with realistic individual head models

et al. 2014

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“…Furthermore, when the media is anisotropic, E (r) is not necessarily in the same direction as j (r), and ρ needs to be a rank-two tensor. However, at the scalp, equation (8) is an excellent approximation to EEG, as the ρ is approximately isotropic in the tangential direction (Rush and Driscoll, 1968;Wolters et al, 2006;Petrov, 2012). meaning comes from Gauss's Law, which in its differential form given by Maxwell is written as…”

Section: Physical Interpretation Of the Surface Laplacianmentioning

confidence: 99%

The surface Laplacian technique in EEG: Theory and methods

Carvalhaes¹,

Barros

2015

International Journal of Psychophysiology

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This paper reviews the method of surface Laplacian differentiation to study EEG. We focus on topics that are helpful for a clear understanding of the underlying concepts and its efficient implementation, which is especially important for EEG researchers unfamiliar with the technique. The popular methods of finite difference and splines are reviewed in detail. The former has the advantage of simplicity and low computational cost, but its estimates are prone to a variety of errors due to discretization. The latter eliminates all issues related to discretization and incorporates a regularization mechanism to reduce spatial noise, but at the cost of increasing mathematical and computational complexity. These and several others issues deserving further development are highlighted, some of which we address to the extent possible. Here we develop a set of discrete approximations for Laplacian estimates at peripheral electrodes and a possible solution to the problem of multiple-frame regularization. We also provide the mathematical details of finite difference approximations that are missing in the literature, and discuss the problem of computational performance, which is particularly important in the context of EEG splines where data sets can be very large. Along this line, the matrix representation of the surface Laplacian operator is carefully discussed and some figures are given illustrating the advantages of this approach. In the final remarks, we briefly sketch a possible way to incorporate finite-size electrodes into Laplacian estimates that could guide further developments.

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“…The construction of a realistic head conductivity model requires accurate segmentation of magnetic resonance (MR) images of the head into tissue classes corresponding to different conductivity values. It is common practice to use five tissue classes-white matter (WM), gray matter (GM), cerebrospinal fluid (CSF), skull, and skin [4,5] followed by manual correction for source localization, although improvements in localization accuracy can be achieved with more classes [6]. Completely manual segmentation [7], typically performed by a clinical expert, is the gold standard.…”

Section: Introductionmentioning

confidence: 99%

Unsupervised Segmentation of Head Tissues from Multi-modal MR Images for EEG Source Localization

et al. 2014

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In this paper, we present and evaluate an automatic unsupervised segmentation method, hierarchical segmentation approach (HSA)-Bayesian-based adaptive mean shift (BAMS), for use in the construction of a patient-specific head conductivity model for electroencephalography (EEG) source localization. It is based on a HSA and BAMS for segmenting the tissues from multi-modal magnetic resonance (MR) head images. The evaluation of the proposed method was done both directly in terms of segmentation accuracy and indirectly in terms of source localization accuracy. The direct evaluation was performed relative to a commonly used reference method brain extraction tool (BET)-FMRIB's automated segmentation tool (FAST) and four variants of the HSA using both synthetic data and real data from ten subjects. The synthetic data includes multiple realizations of four different noise levels and several realizations of typical noise with a 20 % bias field level. The Dice index and Hausdorff distance were used to measure the segmentation accuracy. The indirect evaluation was performed relative to the reference method BET-FAST using synthetic two-dimensional (2D) multimodal magnetic resonance (MR) data with 3 % noise and synthetic EEG (generated for a prescribed source). The source localization accuracy was determined in terms of localization error and relative error of potential. The experimental results demonstrate the efficacy of HSA-BAMS, its robustness to noise and the bias field, and that it provides better segmentation accuracy than the reference method and variants of the HSA. They also show that it leads to a more accurate localization accuracy than the commonly used reference method and suggest that it has potential as a surrogate for expert manual segmentation for the EEG source localization problem.

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Influence of tissue conductivity anisotropy on EEG/MEG field and return current computation in a realistic head model: A simulation and visualization study using high-resolution finite element modeling

Cited by 398 publications

References 44 publications

A finite-element reciprocity solution for EEG forward modeling with realistic individual head models

A finite-element reciprocity solution for EEG forward modeling with realistic individual head models

The surface Laplacian technique in EEG: Theory and methods

Unsupervised Segmentation of Head Tissues from Multi-modal MR Images for EEG Source Localization

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