Abstract
Anisotropy of biological tissues is a low-frequency phenomenon that is associated with the function and structure of cell membranes. Imaging of anisotropic conductivity has potential for the analysis of interactions between electromagnetic fields and biological systems, such as the prediction of current pathways in electrical stimulation therapy. To improve application to the clinical environment, precise approaches are required to understand the exact responses inside the human body subjected to the stimulated currents. In this study, we experimentally evaluate the anisotropic conductivity tensor distribution of canine brain tissues, using a recently developed diffusion tensor-magnetic resonance electrical impedance tomography method. At low frequency, electrical conductivity of the biological tissues can be expressed as a product of the mobility and concentration of ions in the extracellular space. From diffusion tensor images of the brain, we can obtain directional information on diffusive movements of water molecules, which correspond to the mobility of ions. The position dependent scale factor, which provides information on ion concentration, was successfully calculated from the magnetic flux density, to obtain the equivalent conductivity tensor. By combining the information from both techniques, we can finally reconstruct the anisotropic conductivity tensor images of brain tissues. The reconstructed conductivity images better demonstrate the enhanced signal intensity in strongly anisotropic brain regions, compared with those resulting from previous methods using a global scale factor.
Highlights
Estimation of the current pathway and electric fields inside the human body is a critical research topic in relation to the evaluation of the therapeutic effects of electrical stimulation
We experimentally evaluate the anisotropic conductivity tensor distribution of canine brain tissues, using a recently developed diffusion tensor-magnetic resonance electrical impedance tomography method
The resulting color-coded fractional anisotropy (FA) image in Fig. 2(e) represents the directional properties of water diffusion within the brain tissues, which should correspond with the directional alignment of brain tissue
Summary
Estimation of the current pathway and electric fields inside the human body is a critical research topic in relation to the evaluation of the therapeutic effects of electrical stimulation. Noninvasive mapping of the electromagnetic distribution of brain tissues, which have a strong anisotropic characteristic, may play an important role in understanding the neuro-modulatory effects occurring during electrical stimulation therapy. Several research groups have proposed methods for visualizing the distribution of anisotropic conductivity using MR-based electrical impedance tomography (MREIT), which involves the injection of independent currents inside the imaging. Nam et al[5] proposed an advanced method for the implementation of conductivity tensor mapping using projected current density information.[6] Even though they were able to experimentally map the axial anisotropic conductivity distribution of brain tissues, challenges still remain for determining the other components of the conductivity tensor. The demand for innovative techniques to map the conductivity tensor distribution of anisotropic tissues still exists
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