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PIFON-EPT:基于磁共振的电学特性断层成像,采用物理信息傅里叶网络

PIFON-EPT: MR-Based Electrical Property Tomography Using Physics-Informed Fourier Networks.

作者信息

Yu Xinling, Serrallés José E C, Giannakopoulos Ilias I, Liu Ziyue, Daniel Luca, Lattanzi Riccardo, Zhang Zheng

机构信息

Department of Electrical and Computer Engineering, University of California, Santa Barbara, CA 93106 USA.

Research Laboratory of Electronics, Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology, Cambridge, MA 02139 USA.

出版信息

IEEE J Multiscale Multiphys Comput Tech. 2024;9:49-60. doi: 10.1109/jmmct.2023.3345798. Epub 2023 Dec 22.

DOI:10.1109/jmmct.2023.3345798
PMID:39463749
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11501079/
Abstract

We propose Physics-Informed Fourier Networks for Electrical Properties (EP) Tomography (PIFON-EPT), a novel deep learning-based method for EP reconstruction using noisy and/or incomplete magnetic resonance (MR) measurements. Our approach leverages the Helmholtz equation to constrain two networks, responsible for the denoising and completion of the transmit fields, and the estimation of the object's EP, respectively. We embed a random Fourier features mapping into our networks to enable efficient learning of high-frequency details encoded in the transmit fields. We demonstrated the efficacy of PIFON-EPT through several simulated experiments at 3 and 7 tesla(T) MR imaging, and showed that our method can reconstruct physically consistent EP and transmit fields. Specifically, when only 20% of the noisy measured fields were used as inputs, PIFON-EPT reconstructed the EP of a phantom with ≤ 5% error, and denoised and completed the measurements with ≤ 1% error. Additionally, we adapted PIFON-EPT to solve the generalized Helmholtz equation that accounts for gradients of EP between inhomogeneities. This yielded improved results at interfaces between different materials without explicit knowledge of boundary conditions. PIFON-EPT is the first method that can simultaneously reconstruct EP and transmit fields from incomplete noisy MR measurements, providing new opportunities for EPT research.

摘要

我们提出了用于电特性(EP)断层扫描的物理信息傅里叶网络(PIFON-EPT),这是一种基于深度学习的新型方法,用于使用噪声和/或不完整的磁共振(MR)测量进行EP重建。我们的方法利用亥姆霍兹方程来约束两个网络,分别负责发射场的去噪和补全以及物体EP的估计。我们将随机傅里叶特征映射嵌入到我们的网络中,以实现对发射场中编码的高频细节的有效学习。我们通过在3特斯拉和7特斯拉(T)MR成像上进行的几个模拟实验证明了PIFON-EPT的有效性,并表明我们的方法可以重建物理上一致的EP和发射场。具体而言,当仅将20%的噪声测量场用作输入时,PIFON-EPT重建的体模EP误差≤5%,并以≤1%的误差对测量进行去噪和补全。此外,我们调整了PIFON-EPT以求解考虑不均匀性之间EP梯度的广义亥姆霍兹方程。这在不同材料之间的界面处产生了改进的结果,而无需明确的边界条件知识。PIFON-EPT是第一种能够从不完整的噪声MR测量中同时重建EP和发射场的方法,为EPT研究提供了新的机会。

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