Authors: Iliana Marinova, Valentin Mateev

Abstract:

For investigations of electromagnetic field distributions in biological structures by Finite Element Method (FEM), a method for automatic 3D model building of human anatomical objects is developed. Models are made by meshed structures and specific electromagnetic material properties for each tissue type. Mesh is built according to specific FEM criteria for achieving good solution accuracy. Several FEM models of anatomical objects are built. Formulation using magnetic vector potential and scalar electric potential (A-V, A) is used for modeling of electromagnetic fields in human tissue objects. The developed models are suitable for investigations of electromagnetic field distributions in human tissues exposed in external fields during magnetic stimulation, defibrillation, impedance tomography etc.

Keywords: electromagnetic field, finite element method, humantissue.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1081529

Procedia APA BibTeX Chicago EndNote Harvard JSON MLA RIS XML ISO 690 PDF Downloads 5241

References:

[1] S. Zachow, M. Zilske, H-C. Hege. 3D Reconstruction of Individual Anatomy from Medical Image Data: Segmentation and Geometry Proceedings of the 25th CADFEM Users- Meeting 2007, Congress Center Dresden, Germany, November 21-23, 2007.
[2] K. Neubert et al. Model-Based Autosegmentation of Brain Structures in the Honeybee Using Statistical Shape Models, Proc. 8th Int. Congr. of Neuroethology, 2007
[3] J. Cebral , R. Lohner. "From Medical Images to Anatomically Accurate Finite Element Grids". Int. Journal For Numerical Methods in Engineering, 51(8), 2001, pp. 985-1008.
[4] J. Zheng , L. Li, X. Huo. ÔÇ×Analysis of Electric Field in Real Head Model during Transcranial Magnetic Stimulation". Proceedings of the 2005 IEEE Engineering in Medicine and Biology, 27th Annu. Conf., Shang Hai, 2005.
[5] ANSYS Release 12.0 Documentation.
[6] P. Basser, B. Roth. "New currents in electrical stimulation of excitable tissues". Annu. Rev. Biomed. Eng., 02, 2000, pp. 377-397.
[7] P. Tofts, "The distribution of induced current in magnetic stimulation of the nervous system." Phys. Med. Biol. 35, 1990, pp. 1119-1128.
[8] J. Ruohonen, P. Ravazzani, J. Nilsson, M. Panizza, F. Grandori and G. Tognola. "A volume-conduction analysis of magnetic stimulation of peripheral nerves." IEEE Trans. Biomed. Eng. 1996, 43, pp. 669-678.
[9] P. Karu, M. Stuchly. "Quasi-static electric field in a cylindrical volume conductor induced by external coils." IEEE Trans. Biomed. Eng., 41, 1994, pp. 151-158.
[10] B. Roth, J. Saypol, M. Hallet, L. Cohen. "A theoretical calculation of the electric field induced by magnetic stimulation of a peripheral nerve", Muscle & Nerve, 13, 1994, pp. 734-741.
[11] S. Nagarajan, M. Durand. "Analysis of magnetic stimulation of a concentric axon in a nerve bundle." IEEE Trans. Biomed. Eng., 42, 1995, pp. 926-932.
[12] B. Roth, J. Saypol, M. Hallet, L. Cohen. "A theoretical calculation of the electric field induced in the cortex during magnetic stimulation", Electroenceph. Clin. Neurophysiol, 81, 1991, pp. 47-56.
[13] P. Ragan, W. Wang, S. Eisenbrg. ÔÇ×Magnetically induced currents in the canine Heart. A finite element study", IEEE Trans Biomed Eng, 1995, 42, pp. 1110-1116.
[14] V. Krasteva, S. Papazov, I. Daskalov. "Magnetic Stimulation for nonhomogeneous biological structures", BioMed Eng Online 2002, pp. 1:3.
[15] P. Miranda, M. Hallet, P. Basser. The electric field induced in the brain by magnetic stimulation: "A 3D Finite-element analysis of the effect of tissue heterogeneity and anisotropy", IEEE Trans Biomed Eng, 50, 2003, pp. 1074-1085.
[16] J. Malmivuo, J. Plonsey. Bioelectromagnetism. Oxford University Press, New York-Oxford 1995.
[17] U. Pliquett, S. Gallo, S. Hui, Ch. Gusbeth, E. Neumann. "Local and transient structural changes in stratum corneum at high electric fields: contribution of Joule heating", Bioelectrochem., Vol. 67, 2005. pp. 37- 46.