Abstract
Magnetic resonance electrical properties tomography (MREPT) aims to visualize the internal high-frequency conductivity distribution at Larmor frequency using the B1 transceive phase data. From the magnetic field perturbation by the electrical field associated with the radiofrequency (RF) magnetic field, the high-frequency conductivity and permittivity distributions inside the human brain have been reconstructed based on the Maxwell’s equation. Starting from the Maxwell’s equation, the complex permittivity can be described as a second order elliptic partial differential equation. The established reconstruction algorithms have focused on simplifying and/or regularizing the elliptic partial differential equation to reduce the noise artifact. Using the nonlinear relationship between the Maxwell’s equation, measured magnetic field, and conductivity distribution, we design a deep learning model to visualize the high-frequency conductivity in the brain, directly derived from measured magnetic flux density. The designed moving local window multi-layer perceptron (MLW-MLP) neural network by sliding local window consisting of neighboring voxels around each voxel predicts the high-frequency conductivity distribution in each local window. The designed MLW-MLP uses a family of multiple groups, consisting of the gradients and Laplacian of measured B1 phase data, as the input layer in a local window. The output layer of MLW-MLP returns the conductivity values in each local window. By taking a non-local mean filtering approach in the local window, we reconstruct a noise suppressed conductivity image while maintaining spatial resolution. To verify the proposed method, we used B1 phase datasets acquired from eight human subjects (five subjects for training procedure and three subjects for predicting the conductivity in the brain).
Highlights
Various techniques to measure and analyze the electrical properties of biological tissues using a magnetic resonance imaging (MRI) scanner have been developed and experimented [1,2,3,4,5,6,7]
One reason is to use the ground truth conductivity depending on the regularization parameter c of the convection reaction Eq (4) and the other reason relates to the designed moving local window multi-layer perceptron (MLW-MLP) model which includes L2-regularization to stabilize the learning process
We have proposed MLW-MLP neural network that is capable of visualizing the high-frequency conductivity map in the human brain from measured B1 phase signals using a conventional 3 T MRI scanner with significantly improved conductivity image quality
Summary
Various techniques to measure and analyze the electrical properties of biological tissues using a magnetic resonance imaging (MRI) scanner have been developed and experimented [1,2,3,4,5,6,7]. Using a conventional MRI scanner without any external electrical stimulation, magnetic. High-frequency conductivity at Larmor-frequency in human brain
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