Optimized Excitation in Microwave-induced Thermoacoustic Imaging for Artifact Suppression.

Qiang Liu, Weian Chao, Ruyi Wen, Yubin Gong, Lei Xi
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Abstract

Microwave-induced thermoacoustic imaging (M-TAI) allows the visualization of macroscopic and microscopic structures of bio-tissues. However, it suffers from severe inherent artifacts that might misguide the subsequent diagnostics and treatments of diseases. To overcome this limitation, we propose an optimized excitation strategy. In detail, the strategy integrates dynamically compound specific absorption rate (SAR) and co-planar configuration of polarization state, incident wave vector and imaging plane. Starting from the theoretical analysis, we interpret the underlying mechanism supporting the superiority of the optimized excitation strategy to achieve an effect equivalent to homogenizing the deposited electromagnetic energy in bio-tissues. The following numerical simulations demonstrate that the strategy enables better preservation of the conductivity weighting of samples while increasing Pearson correlation coefficient. Furthermore, the in vitro and in vivo M-TAI experiments validate the effectiveness and robustness of this optimized excitation strategy in artifact suppression, allowing the simultaneous identification of both boundary and inside fine structures within bio-tissues. All the results suggest that the optimized excitation strategy can be expanded to diverse scenarios, inspiring more suitable strategies that remarkably suppress the inherent artifacts in M-TAI.

优化微波诱导热声成像中的激励以抑制伪影。
微波诱导热声成像(M-TAI)可实现生物组织宏观和微观结构的可视化。然而,它存在严重的固有伪影,可能会误导后续的疾病诊断和治疗。为了克服这一局限性,我们提出了一种优化的激发策略。具体来说,该策略综合了动态复合比吸收率(SAR)和偏振态、入射波矢量和成像平面的共面配置。从理论分析入手,我们解释了支持优化激发策略优越性的基本机制,以达到等同于在生物组织中均匀沉积电磁能量的效果。接下来的数值模拟证明,该策略能更好地保持样本的电导率权重,同时提高皮尔逊相关系数。此外,体外和体内 M-TAI 实验验证了这种优化激励策略在抑制伪影方面的有效性和稳健性,可同时识别生物组织的边界和内部精细结构。所有这些结果表明,优化的激发策略可以扩展到不同的应用场景,从而激发出更合适的策略,显著抑制 M-TAI 中固有的伪影。
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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