基于磁共振成像中B₁图的电阻抗断层成像：原理、应用与挑战

Electrical Properties Tomography Based on $B_{{1}}$ Maps in MRI: Principles, Applications, and Challenges.

作者信息

Liu Jiaen, Wang Yicun, Katscher Ulrich, He Bin

出版信息

IEEE Trans Biomed Eng. 2017 Nov;64(11):2515-2530. doi: 10.1109/TBME.2017.2725140. Epub 2017 Aug 21.

DOI:10.1109/TBME.2017.2725140

PMID:28829299

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5675043/

Abstract

OBJECTIVE

The purpose is to provide a comprehensive review of the electrical properties tomography (EPT) technique, which was introduced to image the electrical properties (EPs) of tissue noninvasively by exploiting the measured field data of MRI.

METHODS

We reviewed the principle of EPT, reconstruction methods, biomedical applications such as tumor imaging, and existing challenges. As a key application of EPT, the estimation of specific absorption rate (SAR) due to MRI was discussed in the background of elevated risk of tissue heating at high field.

RESULTS AND CONCLUSION

Since the originally proposed local, homogeneous Helmholtz equation-based reconstruction algorithm, advanced EPT algorithms have emerged to address the challenges of EPT, including reconstruction error near tissue boundaries, noise sensitivity, inaccurate phase estimation, and elimination of the unmeasurable component, along with demonstrations of in vivo experiments. EPT techniques have been applied to investigate EPs of both healthy and pathological tissues in vivo and factors contributing to various EP value, including sodium, water content, etc. More studies are anticipated to consolidate the current findings. EPT-based subject-specific SAR estimation has led to in vivo demonstration of its feasibility and prediction of temperature increase of phantom during MRI scans merely using measured data.

SIGNIFICANCE

EPT has the advantage of high resolution and practical feasibility in a clinical setup for imaging the biomedically interesting EPs of tissue in the radiofrequency range. EPT-based SAR estimation is another promising topic for predicting tissue heating of individual subjects during a specific MRI scan.

摘要

目的

旨在对电阻抗断层成像（EPT）技术进行全面综述，该技术通过利用磁共振成像（MRI）的测量场数据对组织的电阻抗特性进行无创成像。

方法

我们回顾了EPT的原理、重建方法、肿瘤成像等生物医学应用以及现存挑战。作为EPT的一项关键应用，在高场下组织发热风险增加的背景下，讨论了MRI引起的比吸收率（SAR）的估计。

结果与结论

自最初提出基于局部、均匀亥姆霍兹方程的重建算法以来，先进的EPT算法不断涌现，以应对EPT面临的挑战，包括组织边界附近的重建误差、噪声敏感性、相位估计不准确以及不可测量分量的消除，同时还展示了体内实验。EPT技术已被应用于研究健康和病理组织在体内的电阻抗特性以及导致各种电阻抗值的因素，包括钠、含水量等。预计会有更多研究来巩固当前的研究结果。基于EPT的个体特异性SAR估计已在体内证明了其可行性，并仅使用测量数据预测了MRI扫描期间体模的温度升高。

意义

EPT在临床环境中对射频范围内组织的生物医学相关电阻抗特性进行成像具有高分辨率和实际可行性的优势。基于EPT的SAR估计是预测特定MRI扫描期间个体受试者组织发热的另一个有前景的课题。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/9078/5675043/37685a12813d/nihms916122f1.jpg

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基于磁共振成像中B₁图的电阻抗断层成像：原理、应用与挑战

Electrical Properties Tomography Based on $B_{{1}}$ Maps in MRI: Principles, Applications, and Challenges.

作者信息

出版信息

OBJECTIVE

METHODS

RESULTS AND CONCLUSION

SIGNIFICANCE

目的

方法

结果与结论

意义

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