Microwave Imaging Based Lesion Monitoring During Infarct Ablation: Feasibility Study

2023 IEEE International Symposium on Antennas and Propagation and USNC-URSI Radio Science Meeting (USNC-URSI) Pub Date : 2023-07-23 DOI:10.1109/USNC-URSI52151.2023.10237557

Sunil Gaddam, Poulami Samaddar, K. Gopalakrishnan, Keirthana Aedma, D. Damani, Suganti Shivaram, Shuvashis Dey, Sayan Roy, Dipankar Mitra, S. P. Arunachalam

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Abstract

Sudden cardiac death rate post-myocardial infarction due to arrhythmia is increasing. Cardiac ablation of infarcts is shown to reduce arrhythmogenic events. Current methods are inadequate to monitor the lesions during infarct ablation. Therefore novel noninvasive tools are necessary to provide real-time monitoring of ablation and to titrate the ablative power to reduce arrhythmogenicity. The purpose of this simulation study was to demonstrate the feasibility of microwave imaging (MWI) to monitor the temperature profile of the lesions during infarct ablation. A 2D model of the left ventricle was used with an infarct region of interest for microwave imaging electromagnetic simulation at 915 MHz using known myocardial dielectric properties and its temperature dependence. Distorted Born Iterative Method (DBIM) was used to reconstruct the relative permittivity that is mapped to the temperature field and compared within the infarct region. Good agreement was observed between the reconstructed and assigned temperature field within the infarct region. The study demonstrates the feasibility of using MWI for the non-invasive assessment of infarct tissue temperatures during ablation.

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基于微波成像的梗死消融过程中病变监测:可行性研究

心梗后心律失常引起的心源性猝死率呈上升趋势。心脏消融术可减少致心律失常事件。目前的方法不足以监测梗死消融过程中的病变。因此，需要新的无创工具来提供消融的实时监测和滴定消融功率以减少心律失常。本模拟研究的目的是证明微波成像(MWI)在梗死消融过程中监测病灶温度分布的可行性。利用已知的心肌介电特性及其对温度的依赖关系，将左心室二维模型与感兴趣的梗死区域一起用于915 MHz微波成像电磁模拟。采用畸变玻恩迭代法(DBIM)重建相对介电常数，将其映射到温度场并在梗死区域内进行比较。重建的温度场与指定的温度场在梗死区有很好的一致性。该研究证明了在消融过程中使用MWI对梗死组织温度进行无创评估的可行性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2023 IEEE International Symposium on Antennas and Propagation and USNC-URSI Radio Science Meeting (USNC-URSI)

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