MR-Based Electrical Property Reconstruction Using Physics-Informed Neural Networks

TL;DR

This paper introduces physics-informed neural networks to reconstruct electrical properties of tissues from MRI data, effectively reducing noise and improving resolution without needing paired training data.

Contribution

It develops a novel physics-informed deep learning approach that directly solves the Helmholtz equation for high-resolution, noise-robust electrical property reconstruction from MRI measurements.

Findings

Effective noise reduction in EP maps

High-resolution EP reconstruction without paired data

Outperforms existing supervised learning methods

Abstract

Electrical properties (EP), namely permittivity and electric conductivity, dictate the interactions between electromagnetic waves and biological tissue. EP can be potential biomarkers for pathology characterization, such as cancer, and improve therapeutic modalities, such radiofrequency hyperthermia and ablation. MR-based electrical properties tomography (MR-EPT) uses MR measurements to reconstruct the EP maps. Using the homogeneous Helmholtz equation, EP can be directly computed through calculations of second order spatial derivatives of the measured magnetic transmit or receive fields $(B_{1}^{+}, B_{1}^{-})$. However, the numerical approximation of derivatives leads to noise amplifications in the measurements and thus erroneous reconstructions. Recently, a noise-robust supervised learning-based method (DL-EPT) was introduced for EP reconstruction. However, the pattern-matching nature of such network does not allow it to generalize for new samples since the network's training is done on a limited number of simulated data. In this work, we leverage recent developments on physics-informed deep learning to solve the Helmholtz equation for the EP reconstruction. We develop deep neural network (NN) algorithms that are constrained by the Helmholtz equation to effectively de-noise the $B_{1}^{+}$ measurements and reconstruct EP directly at an arbitrarily high spatial resolution without requiring any known $B_{1}^{+}$ and EP distribution pairs.