We examined the influence of local tissue conductivity changes in the vicinity of a dipolar source on the neuromagnetic field and the electric scalp potential using a high resolution finite element method model of the human head. We found that the topology of both the electric scalp potential and the neuromagnetic field (and consequently dipole localization) is influenced significantly by conductivity changes only in voxels adjacent to the source. Conductivity changes in these voxels yield a greater change in the amplitude of the magnetic field (and consequently in the dipole strength) than in the amplitude of the electric potential.Der Einfluß der Änderung der lokalen Gewebeleitfahigkeit in der Nähe einer dipolaren Quelle auf das neuromagnetische Feld und das elektrische Potential wird mit Hilfe eines hochauflösenden Finite-Elemente-Modells des menschlichen Kopfes untersucht. Für Leitfähigkeitsänderungen in den Voxeln, die an der Quelle anliegen, wurde eine signifikante Änderung der Topologie (und demzufolge der Dipollokalisation) des magnetischen Feldes und des elektrischen Potentials gefunden. In diesen Voxeln führt die Leitfähigkeitsänderung zu größeren Änderungen in der Amplitude des magnetischen Feldes (und damit der Dipolstärke) als in der Amplitude des elektrischen Potentials

Brauer, Hartmut

Haueisen, Jens

Nowak, Hannes

Ramon, Ceon

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TU Ilmenau | Universitätsbibliothek | ilmedia, 2019 http://www.tu-ilmenau.de/ilmedia Haueisen, Jens; Ramon, Ceon; Brauer, Hartmut; Nowak, Hannes: The Influence of Local Tissue Conductivity Changes on the Magnetoencephalogram and the Electroencephalogram = Der Einfluß der Änderung der lokalen Gewebeleitfähigkeit auf das Elektroenzephalogramm und das Magnetoenzephalogramm Zuerst erschienen in: Biomedizinische Technik = Biomedical Engineering. - Berlin [u.a.] : de Gruyter. - 45 (2000), 7-8, S. 211-214. Erstveröffentlichung: 2000 Datum Digitalisierung: 2009-08-06 ISSN (online): 1862-278X ISSN (print): 0013-5585 DOI: 10.1515/bmte.2000.45.7-8.211 [Zuletzt gesehen: 2019-08-20] „Im Rahmen der hochschulweiten Open-Access-Strategie für die Zweitveröffentlichung identifiziert durch die Universitätsbibliothek Ilmenau.“ “Within the academic Open Access Strategy identified for deposition by Ilmenau University Library.” „Dieser Beitrag ist mit Zustimmung des Rechteinhabers aufgrund einer (DFG-geförderten) Allianz- bzw. Nationallizenz frei zugänglich.“ „This publication is with permission of the rights owner freely accessible due to an Alliance licence and a national licence (funded by the DFG, German Research Foundation) respectively.” Blomedladnische Technik *Band 45 ,n Heft 7-8/2000 The Influence of Local Tissue Conductivity Changes on theMagnetoencephalogram and the Electroencephalogram 211Biomed.'Tectinik: ,·45 (2000), 211-214X Haueisen1 -C. Ramon2 5 .> ,H; Brauer3H, Nowak4The Influence of Local Tissue Conductivity Changes on theMagnetoencephalogram and the ElectroencephalogramDer Einfluß der Änderung der lokalen Gewebeleitfähigkeit auf das Elek-troenzephalogramm und das MagnetoenzephalogrammiBiomagnetisches Zentrum, Klinik fur Neurologic, Friedrich-Schiller- Universität Jena-_ "- ^Department of Electrical Engineering, University of Washington, USA3Institut für Allgemeine und Theoretische Elektrotechnik, Technische Universität Ilmenau, , ' , . * 4JENASENSORIC e.V., JenaKey words: Tissue conductivity - finite element method - FEM - EEG - MEGWe examined the influence of local tissue conductivity changes in the vicinity of a dipolar sourceon the neuromagnetic field and the electric scalp potential using a high resolution finite elementf method model of the human head. We found that the topology of both the electric scalp potenti-al and the neuromagnetic field (and consequently dipole localization) is influenced significantly1 by conductivity changes only in voxels adjacent to the source. Conductivity changes in these vo-, xels yield a greater change in the amplitude of the magnetic field (and consequently in the dipo-le strength) than in the amplitude of the electric potential.^Schlüsselwörter: Elektrische Leitfähigkeit, Finite-Elemente-Methode, FEM, EEG, MEGDer Einfluß der Änderung der lokalen Gewebeleitfahigkeit in der Nähe einer dipolaren Quelleauf das neuromagnetische Feld und das elektrische Potential wird mit Hilfe eines hochauflosen-den Finite-Elemente-Modells des menschlichen Kopfes untersucht. Für Leitfähigkeitsanderun-gen in den Voxeln, die an der Quelle anliegen, wurde eine signifikante Änderung der Topologie(und demzufolge der Dipollokalisation) des magnetischen Feldes und des elektrischen Potentials- gefunden. In diesen Voxeln führt die Leitfähigkeitsänderung zu größeren Änderungen in derAmplitude des magnetischen Feldes (und damit der Dipolstarke) als in der Amplitude des elek-trischen Potentials.l IntroductionRecently, a study by Baumann et aL [1] f oiuid that theelectrical conductivity of cerebrospinal fluid (csf) wasunderestimated by as much as 44 % for nearly two de-cades. Given the difficulties in estimating in vivo con-ductivity values [6] it is not unlikely that the conduc-tivity of other tissues is not correctly estimated, either.However, these conductivity values are required forforward and inverse modeling in magnetoencephalo-graphy (MEG)" and electroencephalography (EEG). ;: A technique which extracts the conductivity infor-mation from diffusion tensor magnetic resonance ima-ging (MRI) proposed by Tuch et al. [7] is likely to over-come these problems; With this technique, the indivi-dual conductivity information of every patient can beused for modeling in MEG And EEG, Thi* techniquedoes not rel/imtissue elassiflcation or compartmentsegmentation but4 on'the1 overlay of anatomical andconductivity^nfonnAtion obtained by MRL Tissue $eg*mentation, therefore, 1* not needed anymore for thoseparts' of ,thf hea^wher^ cbhdu information iiavailable,"However, this modeling technique is influenced bythe signal to noise ratio of the two MRI data sets andthe errors introduced by overlaying the anatomicaland the conductivity MRI information. In order toquantify the influence of such possible errors we com-puted neuromagnetic fields and electric scalp potenti-als by using an isotropic high resolution finite elementmethod (FEM) model of the human head.Since we expect the strongest influence in the vici-nity of the source, the aim of this paper is to examinethe influence of local tissue conductivity changes inthe vicinity of the source on the neuromagnetic fieldsand the electric scalp potentials.2 Methods ,The FEM model of the human head was constructedout of 128 sagittal MRI slices with a slice thickness of2mm. -. Thirteen different tissue types were segmented andassigned to conductivity value in order to describethe conductivity profile of the human head. The finiteelement mesh was generated by connecting slices.Bereitgestellt von | Technische Universität IlmenauAngemeldetHeruntergeladen am | 20.08.19 15:37212The Influence of Local Tissue Conductivity Changes on theMagnetoencephologram and the ElectroencephalogramBiomedizinische TechnikBand 45 Heft 7-8/20 Odipolo positionFigure 1. A slice with classified tissues (top) and the corre-sponding MRI scan (bottom). The original size was 512 χ 512pixel, the bottom portions were cut off. The classified slice re-presents the FEM model cross section In the classified slicedifferent tissue types are represented by different gray values.The origin of the coordinate system is at the lower left cornerof the first slice. The dipole points into the ζ direction (intothe drawing plane)In this way a uniform grid of 452,162 hexahedral ele-ments (voxels) with a resolution of 2 mm was establis-hed. Fig. 1 shows a cross section of the FEM model andthe corresponding MRI slice. The model had been usedand validated previously [3]. We used a tangential(with respect to the closest point on the scalp) dipolarsource in the somatosensory cortex at the position re-presenting the knee. The source was modeled by twofixed voltages at adjacent nodes.The magnetic fields were computed in a samplingplane (15 χ 15 grid, spacing of 1.0 cm χ 1.25 cm) loca-ted at a distance of 1.2 cm above the head. The sam-pling plane was brought into such a position that thedipole location corresponded to the middle of the sam-pling plane. The surface potentials were computed onthe scalp close to the position of the dipole (13 χ 13grid, spacing of 0.6 cm, common average reference).In order to assess the influence of local conductivitychanges, we varied the conductivity value of single vo-xels in the vicinity of the source. Fig. 2 shows the FEMgrid in the vicinity of the source and the voxels inwhich the conductivity was varied (A-F). The conduc-tivity value of csf (cerebrospinal fluid) was 1.78 S/m,the value of gray matter was 0.33 S/m, and the value ofwhite matter was 0.14 S/m.The changes in the magnetic field and electric po-tential were determined by two methods. The changesin field topography were assessed by the correlationcoefficient and the changes in field strength were ex-pressed as a percentage of the difference of the absolu-te amplitudes. In inverse dipole computations changesin the field or potential topography indicate differentsource positions whereas changes in the field or poten-tial strength indicate differences in the sourcestrength.All computations were performed at a workstation(IBM RS/6000 model 370). Depending on the initialguess for the voltage distribution and the source mo-del, between 3000 and 5 000 iterations of the SOR (suc-cessive over relaxation) solver were necessary to ensu-re convergence. The average CPU time for one iterati-on was 2 seconds.3 ResultsFig. 3 shows the magnetic field profiles computedwith the standard model and the model in which voxelA was changed from gray matter to csf conductivity.The two profiles depicted represent the greatest chan-ge observed in this study.Tables 1 and 2 show the correlation coefficientsand amplitude changes for selected conductivity chan-ges of the voxels depicted in figure 1.dipole positionFigure 2. A part of the FEM model of the head in the vicinityof the source (view on the postcentral gyrus in a'sagittal slice).The letters A-F identify the voxels varied.Bereitgestellt von | Technische Universität IlmenauAngemeldetHeruntergeladen am | 20.08.19 15:37iomedi ittischeTechnikTBand45 ·** Heft 7*8/2000:'The Influence of Local Tissue Conductivity Changes on theMagnetoencephalogram and the Electroencephalogram 213o . v / ;;/;.;"'s ;.;;"·: 10Figure 3. Top: Magnetic field isocontour lines computed withthe standard model (mean conductivities). Bottom: Magneticfield isocontour lines computed with voxel A changed fromgray matter to csf conductivity. The magnetic field values areinfT, - - , -As expected, a conductivity change in voxel A pro-duced the largest influence on the magnetic field andalso on the electric potential· In this voxel, the ampli-tude of the magnetic field,was more strongly influen-ced than the electric potential amplitude. Furthermo-re, only conductivity changes in voxel A showed a sig-nificant influence on the magnetic field and the electricpotential topology, _ ; ; ,For a simultaneous change of the voxels B, C, D, E,and F from gray matter conductivity to csf conductivi-ty, the correlation coefficient was above 0.9999 and theamplitude change less than 2 % for both the magneticfield and the electric potential.4 Discussion "'** Λ " Λ " ' °- * ^i - - V^'^-iv*-^" -' ^ - * - ; · - , .According to our experiences, a correlation coefficientof 0.88 could produce a dipolar source localization er*ror of up to 1,5 cm (average about ä~8 mm) while acorrelation coefficient above 0,99 will result in not mo*re than approximately. 1 mm localization error {2,6J,Thus, only change» in the conductivity in the voxelsadjacent to31Jie dipolar source will yield errors in sour-»ce localization prooedure»,^The Amplitude change» ob*'served translate^th Approximately th0 iame percen-tage value into dipolar source strength changes.Our results are in good agreement with a recentstudy investigating the influence of ventricles and lesi-ons on MEG based dipole localization results [9]. Theyfound a significant influence only for such dipoleswhich are very close to lesion or ventricle. This is alsoconfirmed by earlier work of Ueno et al. [8] showingthat even within simple spherical volume conductorsinhomogeneities close to sources can significantly af-fect the measured MEG and EEG.Previously, we investigated the influence of globalconductivity changes on MEG and EEG and foundthat an accurate modeling of magnetic field and elec-tric potential strength requires accurate knowledge oftissue conductivities, while for source localization pro-cedures this knowledge might not be necessary [4]. Inconcordance with this previous study the local con-ductivity changes seem to have a stronger influence onthe field strength (i. e. dipole strength estimation) thanon the field topology (i. e. dipole localization). In con-trast to this previous study, local conductivity changesclose to the source have a small but significant influen-ce on source localization, too.The following limitations of the work presented areimportant. We considered only a single dipolar sourcewhich is the source model most widely used inMEG/EEG studies. The influence of extended or multi-ple sources remains to be investigated. Additionally,our results are based on isotropic tissue conductivities.We assume that the inclusion of tissue anisotropy willfurther influence the magnetic fields and electric po-tentials.In conclusion, it seems that the relatively smallconductivity changes, which could be possibly intro-duced by low signal to noise ratio or artifacts in theconductivity information obtained from MRI, mightnot have a great influence on source localizations.Table 1: Correlation coefficients.VoxelAABCDEFGray matter Correlation coefficientchanged to Electric potential Magnetic fieldcsf 0.986935 0.989456white 0.999672 0.999418csf 0.999989 0,999991white 1.0 1.0csf 0.999992 0 999990white 1.0 1.0csf 1.0 1.0Table 2. Amplitude changes.Voxel dray matter Amplitude change in %^ ι changed to Electric potential Magnetic fieldcsf - 10.96 62.62white 2.06 7.57eaf f 0,02 0,13white 0,05 0.01cef , 1.12 0.50White 0.07 003-, cef 0.13 0,05Bereitgestellt von | Technische Universität IlmenauAngemeldetHeruntergeladen am | 20.08.19 15:37214The Influence of Local Tissue Conductivity Changes on th£Magnetoencephalogram and the ElectroencephalogramBiomedizinischo TechnikBand 45/; Heft 7-8/2000AcknowledgmentsThis work was supported by a joint travel grant fromthe National Science Foundation (NSF) and the Ger-man Academic Exchange Agency (DAAD).References:[1] Baumann, S. B., D. R. Wozny, S. K. Kelly, F, M. Meno:The electrical conductivity of human cerebrospinalfluid at body temperature. IEEE Transactions on Bio-medical Engineering 44 (3): 220-223,1997.[2] Haueisen, J., A. Bottner, H. Nowak, H. Brauer, C. Weil-ler. The influence of conductivity changes in boundaryelement compartments on the forward and inverse pro-blem in electroencephalography and magnetoencepha-lography. Biomedizmische Technik 44 (6): 150-157,1999.[3] Haueisen, J., C. Ramon, P. Czapski, M. Eiselt: On theinfluence of volume currents and extended sources onneuromagnetic fields: A simulation study. Annals ofBiomedical Engineering 23 (11)· 728-739,1995,[4] Haueisen, J., C. Ramon, M. Eiselt, H. Nowak: Influenceof tissue resistivities on neuromagnetic fields and elec-tric potentials studied with a finite element model ofthe head. IEEE Transactions on Biomedical Enginee-ring 44: 727-735,1997.[5] Jasbinsek, V., R. Hren: Influence of randomly displacedBSPM leads on the identification of ventricular preex-citation cites. Biomedizinische Technik, 44 (Supp. 2):104-107,1999.[6] Okada, Y, C,, J.-C, Huang, M, E, Rice, D, Tranchina, C,Nicholson: Origin of the apparent tissue conductivityin the molecular and granular layers of the in'vitroturtle cerebellum and the interpretation of r CurrentSource-Density analysis. Journal of Neurophysiology72 (2): 742-753,1994, ' . ' / - ' -' ">Γ r^* ^[7] Tuch, D. S., V. J, Wedeen, A. M, Dale^ J, W, Belliveau:Electrical conductivity tensor map of the human brain- using NMR diffusion imagingr An effective medium ap-proach. In Proc- Sixth Ann. Meeting Intr S'oc^ Magn.Res,Med., Sydney, Australia, 1998. *·-*,'r' --*"^^\~-[8] Ueno, S., K. Iramina, K. Harada: Effects of inhomoge-neities in cerebral modeling for magnetoencephalogra-phy. IEEE Transactions on Magnetics 23; 3753-3755,1987. . , ' - 4 ß-,ν|-ü·ß"Λ[9] van den Broek, S. P., F. Reinders, M. Donderwinkel, M!J. Peters: Volume conduction effects in eeg" and meg.Electroencephalography and clinical Neurophysiology,106:522-534,1998,. Korrespondenzanschrift:Jens Haueisen' ^ „ .Biomagnetisches Zentrum"Friednch-SchiUer-Universit t Jena ^Philosophenwegs ^ f .D-07743 Jena, Germany ·Phone: +49-3641-935338"^Fax:+49-3641-935355E-Mail: haueisen@biomag.uni-jena.deBereitgestellt von | Technische Universität IlmenauAngemeldetHeruntergeladen am | 20.08.19 15:37

Der Einfluß der Änderung der lokalen Gewebeleitfähigkeit auf das Elektroenzephalogramm und das Magnetoenzephalogramm

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Der Einfluß der Änderung der lokalen Gewebeleitfähigkeit auf das Elektroenzephalogramm und das Magnetoenzephalogramm

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