Temperature-Induced Contrast Enhancement for Radar-Based Breast Tumor Detection at K-Band Using Tissue Mimicking Phantoms

IF 3 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC
Jochen Moll;Teresa Slanina;Jonathan Stindl;Thomas Maetz;Duy Hai Nguyen;Viktor Krozer
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引用次数: 0

Abstract

Conventional approaches for microwave breast tumor detection are limited by the imaging resolution due to the low operating frequency. The objective of this work is to provide a proof of concept for radar-based detection of breast tumors in K-band using the temperature-dependent permittivity of the tissue for contrast enhancement. The innovation of this work is given by i) investigating higher microwave frequencies for breast cancer diagnostics and improved resolution; ii) exploiting variations in tissue temperature as a non-invasive approach for contrast-induced radar imaging eliminating the need for contrast agents such as nanoparticles; iii) using a well-defined setup with the breast compressed similar to mammography; iv) eliminating the need for coupling liquid through the usage of ultra-wideband bow-tie antennas operating from 16.55 to 40 GHz for a reflection coefficient lower than −10 dB; v) validating the experimental findings through numerical modelling. The experimental setup in this work consists of a single-pixel transmission setup with the antennas placed in a 3D printed container. Two different tissue mimicking phantoms have been studied that both model the temperature-dependent permittivity of biological tissue. The first phantom represents homogeneous fatty tissue properties and the second phantom simulates fatty tissue with a tumor inclusion. A uniform phantom warming is realized through a water bath combined with a continuous monitoring of the phantoms temperature. We show that a homogeneous phantom without tumor can be distinguished from a heterogeneous phantom with tumor in the temperature range of 28 $^\circ$ C to 38 $^\circ$ C.
利用组织模拟Phantoms在K波段进行基于雷达的乳腺肿瘤检测的温度诱导对比度增强
用于微波乳腺肿瘤检测的常规方法由于低操作频率而受到成像分辨率的限制。这项工作的目的是利用组织的温度相关介电常数来增强对比度,为基于雷达的K波段乳腺肿瘤检测提供概念验证。这项工作的创新在于:i)研究用于乳腺癌症诊断的更高微波频率和提高的分辨率;ii)利用组织温度的变化作为对比度诱导的雷达成像的非侵入性方法,消除了对造影剂例如纳米颗粒的需要;iii)使用明确定义的设置,其中乳房被压缩,类似于乳房X光照相术;iv)通过使用从16.55到40GHz操作的超宽带蝴蝶结天线来消除对耦合液体的需要,反射系数低于−10dB;v) 通过数值模拟验证了实验结果。这项工作中的实验装置包括一个单像素传输装置,天线放置在3D打印的容器中。已经研究了两种不同的组织模拟体模,它们都对生物组织的温度相关介电常数进行了建模。第一个体模代表均匀的脂肪组织特性,第二个体模模拟含有肿瘤的脂肪组织。通过水浴结合对幻影温度的连续监测来实现均匀的幻影加热。我们发现,在28$^\circ$C到38$^\circ$C的温度范围内,没有肿瘤的同质体模可以与有肿瘤的异质体模区分开来。
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来源期刊
CiteScore
5.80
自引率
9.40%
发文量
58
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