CutFEM forward modeling for EEG source analysis

Tim Erdbrügger; Andreas Westhoff; Malte Höltershinken; Jan-Ole Radecke; Yvonne Buschermöhle; Alena Buyx; Fabrice Wallois; Sampsa Pursiainen; Joachim Gross; Rebekka Lencer; Christian Engwer; Carsten Wolters

doi:10.3389/fnhum.2023.1216758

CutFEM forward modeling for EEG source analysis

Tim Erdbrügger, Andreas Westhoff, Malte Höltershinken, Jan-Ole Radecke, Yvonne Buschermöhle, Alena Buyx, Fabrice Wallois, Sampsa Pursiainen, Joachim Gross, Rebekka Lencer, Christian Engwer, Carsten Wolters

Klinik für Psychiatrie und Psychotherapie

9 Zitate (Scopus)

Abstract

INTRODUCTION: Source analysis of Electroencephalography (EEG) data requires the computation of the scalp potential induced by current sources in the brain. This so-called EEG forward problem is based on an accurate estimation of the volume conduction effects in the human head, represented by a partial differential equation which can be solved using the finite element method (FEM). FEM offers flexibility when modeling anisotropic tissue conductivities but requires a volumetric discretization, a mesh, of the head domain. Structured hexahedral meshes are easy to create in an automatic fashion, while tetrahedral meshes are better suited to model curved geometries. Tetrahedral meshes, thus, offer better accuracy but are more difficult to create.

METHODS: We introduce CutFEM for EEG forward simulations to integrate the strengths of hexahedra and tetrahedra. It belongs to the family of unfitted finite element methods, decoupling mesh and geometry representation. Following a description of the method, we will employ CutFEM in both controlled spherical scenarios and the reconstruction of somatosensory-evoked potentials.

RESULTS: CutFEM outperforms competing FEM approaches with regard to numerical accuracy, memory consumption, and computational speed while being able to mesh arbitrarily touching compartments.

DISCUSSION: CutFEM balances numerical accuracy, computational efficiency, and a smooth approximation of complex geometries that has previously not been available in FEM-based EEG forward modeling.

Originalsprache	Englisch
Zeitschrift	Frontiers in Human Neuroscience
Jahrgang	17
Seiten (von - bis)	1216758
ISSN	1662-5161
DOIs	https://doi.org/10.3389/fnhum.2023.1216758
Publikationsstatus	Veröffentlicht - 2023

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Forschungsschwerpunkt: Gehirn, Hormone, Verhalten - Center for Brain, Behavior and Metabolism (CBBM)

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1.22-01 Allgemeine, Kognitive und Mathematische Psychologie

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10.3389/fnhum.2023.1216758

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title = "CutFEM forward modeling for EEG source analysis",

abstract = "INTRODUCTION: Source analysis of Electroencephalography (EEG) data requires the computation of the scalp potential induced by current sources in the brain. This so-called EEG forward problem is based on an accurate estimation of the volume conduction effects in the human head, represented by a partial differential equation which can be solved using the finite element method (FEM). FEM offers flexibility when modeling anisotropic tissue conductivities but requires a volumetric discretization, a mesh, of the head domain. Structured hexahedral meshes are easy to create in an automatic fashion, while tetrahedral meshes are better suited to model curved geometries. Tetrahedral meshes, thus, offer better accuracy but are more difficult to create.METHODS: We introduce CutFEM for EEG forward simulations to integrate the strengths of hexahedra and tetrahedra. It belongs to the family of unfitted finite element methods, decoupling mesh and geometry representation. Following a description of the method, we will employ CutFEM in both controlled spherical scenarios and the reconstruction of somatosensory-evoked potentials.RESULTS: CutFEM outperforms competing FEM approaches with regard to numerical accuracy, memory consumption, and computational speed while being able to mesh arbitrarily touching compartments.DISCUSSION: CutFEM balances numerical accuracy, computational efficiency, and a smooth approximation of complex geometries that has previously not been available in FEM-based EEG forward modeling.",

author = "Tim Erdbr{\"u}gger and Andreas Westhoff and Malte H{\"o}ltershinken and Jan-Ole Radecke and Yvonne Buscherm{\"o}hle and Alena Buyx and Fabrice Wallois and Sampsa Pursiainen and Joachim Gross and Rebekka Lencer and Christian Engwer and Carsten Wolters",

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year = "2023",

doi = "10.3389/fnhum.2023.1216758",

language = "English",

volume = "17",

pages = "1216758",

journal = "Frontiers in Human Neuroscience",

issn = "1662-5161",

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T1 - CutFEM forward modeling for EEG source analysis

AU - Erdbrügger, Tim

AU - Westhoff, Andreas

AU - Höltershinken, Malte

AU - Radecke, Jan-Ole

AU - Buschermöhle, Yvonne

AU - Buyx, Alena

AU - Wallois, Fabrice

AU - Pursiainen, Sampsa

AU - Gross, Joachim

AU - Lencer, Rebekka

AU - Engwer, Christian

AU - Wolters, Carsten

PY - 2023

Y1 - 2023

N2 - INTRODUCTION: Source analysis of Electroencephalography (EEG) data requires the computation of the scalp potential induced by current sources in the brain. This so-called EEG forward problem is based on an accurate estimation of the volume conduction effects in the human head, represented by a partial differential equation which can be solved using the finite element method (FEM). FEM offers flexibility when modeling anisotropic tissue conductivities but requires a volumetric discretization, a mesh, of the head domain. Structured hexahedral meshes are easy to create in an automatic fashion, while tetrahedral meshes are better suited to model curved geometries. Tetrahedral meshes, thus, offer better accuracy but are more difficult to create.METHODS: We introduce CutFEM for EEG forward simulations to integrate the strengths of hexahedra and tetrahedra. It belongs to the family of unfitted finite element methods, decoupling mesh and geometry representation. Following a description of the method, we will employ CutFEM in both controlled spherical scenarios and the reconstruction of somatosensory-evoked potentials.RESULTS: CutFEM outperforms competing FEM approaches with regard to numerical accuracy, memory consumption, and computational speed while being able to mesh arbitrarily touching compartments.DISCUSSION: CutFEM balances numerical accuracy, computational efficiency, and a smooth approximation of complex geometries that has previously not been available in FEM-based EEG forward modeling.

AB - INTRODUCTION: Source analysis of Electroencephalography (EEG) data requires the computation of the scalp potential induced by current sources in the brain. This so-called EEG forward problem is based on an accurate estimation of the volume conduction effects in the human head, represented by a partial differential equation which can be solved using the finite element method (FEM). FEM offers flexibility when modeling anisotropic tissue conductivities but requires a volumetric discretization, a mesh, of the head domain. Structured hexahedral meshes are easy to create in an automatic fashion, while tetrahedral meshes are better suited to model curved geometries. Tetrahedral meshes, thus, offer better accuracy but are more difficult to create.METHODS: We introduce CutFEM for EEG forward simulations to integrate the strengths of hexahedra and tetrahedra. It belongs to the family of unfitted finite element methods, decoupling mesh and geometry representation. Following a description of the method, we will employ CutFEM in both controlled spherical scenarios and the reconstruction of somatosensory-evoked potentials.RESULTS: CutFEM outperforms competing FEM approaches with regard to numerical accuracy, memory consumption, and computational speed while being able to mesh arbitrarily touching compartments.DISCUSSION: CutFEM balances numerical accuracy, computational efficiency, and a smooth approximation of complex geometries that has previously not been available in FEM-based EEG forward modeling.

U2 - 10.3389/fnhum.2023.1216758

DO - 10.3389/fnhum.2023.1216758

M3 - Journal articles

C2 - 37694172

SN - 1662-5161

VL - 17

SP - 1216758

JO - Frontiers in Human Neuroscience

JF - Frontiers in Human Neuroscience

ER -

CutFEM forward modeling for EEG source analysis

Abstract

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