On the Feasibility of a High-Sensitivity Imaging System for Biomedical Applications Based on Low-Frequency Magnetic Field

IF 3 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC
Sabrina Rotundo;Danilo Brizi;Agostino Monorchio
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引用次数: 0

Abstract

In this article, the theoretical and experimental feasibility analyses of a high-sensitivity imaging system for non-invasive detection of pathological inclusions within biological tissues are presented. The radiating system, exploiting a low frequency magnetic field operating at 3 MHz, consists of an inner resonant spiral sensor, inductively coupled to an unloaded external planar probe loop. The proposed configuration produces a focused magnetic field distribution, therefore a high-sensitivity imaging with respect to the wavelength can be accomplished (detecting inclusions with size in the order of λ/10000, i.e., 1 cm). In particular, the inclusion detection is carried out by observing the amplitude shift of the external probe loop input impedance while scanning the region of interest, leading to a non-invasive and contactless imaging procedure. In addition, we demonstrate the possibility to detect an inclusion, placed within the investigated tissue, either with or without the use of a ferromagnetic contrast medium. To evaluate the proposed imaging system effectiveness, we first perform full-wave numerical simulations. Then, we report the experimental measurements acquired over a fabricated prototype interacting with a representative biological phantom, observing a very good agreement with the numerical simulations. The results confirm the potential for an innovative near-field imaging system to be employed for non-invasive detection of malignant inclusions, expanding the adoption of low RF frequencies in biomedical applications.
基于低频磁场的生物医学高灵敏度成像系统的可行性研究
本文介绍了一种用于生物组织内病理内含物无创检测的高灵敏度成像系统的理论和实验可行性分析。该辐射系统利用工作频率为3mhz的低频磁场,由一个内部谐振螺旋传感器组成,该传感器与一个未加载的外部平面探头环路电感耦合。所提出的配置产生了一个聚焦的磁场分布,因此可以实现相对于波长的高灵敏度成像(检测大小为λ/10000的夹杂物,即1 cm)。特别是,在扫描感兴趣的区域时,通过观察外部探针环路输入阻抗的幅度位移来进行夹杂物检测,从而实现非侵入性和非接触式成像过程。此外,我们证明了检测包涵体的可能性,放置在研究组织内,无论使用或不使用铁磁造影剂。为了评估所提出的成像系统的有效性,我们首先进行了全波数值模拟。然后,我们报告了在一个制造的原型上获得的实验测量结果,这些测量结果与数值模拟结果非常吻合。研究结果证实了一种创新的近场成像系统用于恶性包涵体的非侵入性检测的潜力,扩大了低射频在生物医学应用中的应用。
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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来源期刊
CiteScore
5.80
自引率
9.40%
发文量
58
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