İhsan Oğuz Tanzer scite author profile

İhsan Oğuz Tanzer

5Publications

55Citation Statements Received

68Citation Statements Given

How they've been cited

How they cite others

116

Affiliations

Aalto University, Sağlık Bilimleri Üniversitesi, Üsküdar University

Publications

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Forward problem solution of electromagnetic source imaging using a new BEM formulation with high-order elements

Gençer

Tanzer²

1999

Phys. Med. Biol.

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Representations of the active cell populations on the cortical surface via electric and magnetic measurements are known as electromagnetic source images (EMSIs) of the human brain. Numerical solution of the potential and magnetic fields for a given electrical source distribution in the human brain is an essential part of electromagnetic source imaging. In this study, the performance of the boundary element method (BEM) is explored with different surface element types. A new BEM formulation is derived that makes use of isoparametric linear, quadratic or cubic elements. The surface integration is performed with Gauss quadrature. The potential fields are solved assuming a concentric three-shell model of the human head for a tangential dipole at different locations. In order to achieve 2% accuracy in potential solutions, the number of quadratic elements is of the order of hundreds. However, with linear elements, this number is of the order of ten thousand. The relative difference measures (RDMs) are obtained for the numerical models that use different element types. The numerical models that employ quadratic and cubic element types provide superior performance over linear elements in terms of accuracy in solutions. Assuming a homogeneous sphere model of the head, the RDMs are also obtained for the three components (radial and tangential) of the magnetic fields. The RDMs obtained for the tangential fields are, in general, much higher than those obtained for the radial fields. Both quadratic and cubic elements provide superior performance compared with linear elements for a wide range of dipole locations.

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Representation of bioelectric current sources using Whitney elements in the finite element method

Tanzer¹,

Järvenpää²,

Nenonen³

et al. 2005

Phys. Med. Biol.

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Bioelectric current sources of magneto- and electroencephalograms (MEG, EEG) are usually modelled with discrete delta-function type current dipoles, despite the fact that the currents in the brain are naturally continuous throughout the neuronal tissue. In this study, we represent bioelectric current sources in terms of Whitney-type elements in the finite element method (FEM) using a tetrahedral mesh. The aim is to study how well the Whitney elements can reproduce the potential and magnetic field patterns generated by a point current dipole in a homogeneous conducting sphere. The electric potential is solved for a unit sphere model with isotropic conductivity and magnetic fields are calculated for points located on a cap outside the sphere. The computed potential and magnetic field are compared with analytical solutions for a current dipole. Relative difference measures between the FEM and analytical solutions are less than 1%, suggesting that Whitney elements as bioelectric current sources are able to produce the same potential and magnetic field patterns as the point dipole sources.

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Dosimetric Comparison of Superflab and Specially Prepared Bolus Materials Used in Radiotherapy Practice

Aras¹,

Tanzer²,

İkizceli³

2020

Eur J Breast Health

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The role of melatonin on acute thyroid damage induced by high dose rate X-ray in head and neck radiotherapy

Aras

Tanzer

Can

et al. 2021

Radiation Physics and Chemistry

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A new boundary element method formulation for the forward problem solution of electro-magnetic source imaging

Tanzer

Gençer²

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