%0 Journal Article %1 Chen:2009:J-Neurosci-Methods:19428517 %A Chen, M %A Mogul, D J %D 2009 %J J Neurosci Methods %K model simulation tms %N 1 %P 111-120 %R 10.1016/j.jneumeth.2009.01.010 %T A structurally detailed finite element human head model for simulation of transcranial magnetic stimulation %U http://www.ncbi.nlm.nih.gov/pubmed/19428517 %V 179 %X Computational studies of the head utilizing finite element models (FEMs) have been used to investigate a wide variety of brain-electromagnetic (EM) field interaction phenomena including magnetic stimulation of the head using transcranial magnetic stimulation (TMS), direct electric stimulation of the brain for electroconvulsive therapy, and electroencephalography source localization. However, no human head model of sufficient complexity for studying the biophysics under these circumstances has been developed which utilizes structures at both the regional and cellular levels and provides well-defined smooth boundaries between tissues of different conductivities and orientations. The main barrier for building such accurate head models is the complex modeling procedures that include 3D object reconstruction and optimized meshing. In this study, a structurally detailed finite element model of the human head was generated that includes details to the level of cerebral gyri and sulci by combining computed tomography and magnetic resonance images. Furthermore, cortical columns that contain conductive processes of pyramidal neurons traversing the neocortical layers were included in the head model thus providing structure at or near the cellular level. These refinements provide a much more realistic model to investigate the effects of TMS on brain electrophysiology in the neocortex.

@article{Chen:2009:J-Neurosci-Methods:19428517, abstract = {Computational studies of the head utilizing finite element models (FEMs) have been used to investigate a wide variety of brain-electromagnetic (EM) field interaction phenomena including magnetic stimulation of the head using transcranial magnetic stimulation (TMS), direct electric stimulation of the brain for electroconvulsive therapy, and electroencephalography source localization. However, no human head model of sufficient complexity for studying the biophysics under these circumstances has been developed which utilizes structures at both the regional and cellular levels and provides well-defined smooth boundaries between tissues of different conductivities and orientations. The main barrier for building such accurate head models is the complex modeling procedures that include 3D object reconstruction and optimized meshing. In this study, a structurally detailed finite element model of the human head was generated that includes details to the level of cerebral gyri and sulci by combining computed tomography and magnetic resonance images. Furthermore, cortical columns that contain conductive processes of pyramidal neurons traversing the neocortical layers were included in the head model thus providing structure at or near the cellular level. These refinements provide a much more realistic model to investigate the effects of TMS on brain electrophysiology in the neocortex.}, added-at = {2014-02-23T18:05:47.000+0100}, author = {Chen, M and Mogul, D J}, biburl = {https://www.bibsonomy.org/bibtex/2061ac60d4216fa68649e9807d6dee23a/agredain}, description = {A structurally detailed finite element hu... [J Neurosci Methods. 2009] - PubMed - NCBI}, doi = {10.1016/j.jneumeth.2009.01.010}, interhash = {4bc40c4c85aa89f544590f0479cdf41a}, intrahash = {061ac60d4216fa68649e9807d6dee23a}, journal = {J Neurosci Methods}, keywords = {model simulation tms}, month = apr, number = 1, pages = {111-120}, pmid = {19428517}, timestamp = {2014-02-23T18:05:47.000+0100}, title = {A structurally detailed finite element human head model for simulation of transcranial magnetic stimulation}, url = {http://www.ncbi.nlm.nih.gov/pubmed/19428517}, volume = 179, year = 2009 }