Basic study of a new diagnostic modality by non-invasive measurement of the electrical impedance tomography (EIT) on localized tissues

Kenji Okazaki, A. Tangoku, T. Morimoto, Keigo Hattori, Ryosuke Kotani, E. Yasuno, M. Akutagawa, Y. Kinouchi
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引用次数: 6

Abstract

Information on biological tissues for medical diagnoses can be usually provided by X-ray images, ultrasonic images and MRI, which offer basically the information on mass or proton density distributions. On the other hands, electrical bioimpedances contain different information related to tissue structures and their physiological states and functions. It is well known that the electrical properties of biological tissues differ significantly depending on their structure. This has been reported by investigators studying the application of differences in the electrical properties of tumors to the clinical aspect. Electrical properties of malignant breast tumors have been investigated by Frinke and Morse. They found significantly higher permeability of the tumor tissue at 20 kHz compared to normal or nonmalignant tissues. Similar results have been reported by several other investigations. Our group has measured directly electrical impedances of benign breast tumor and malignant breast tumor by needle electrodes. Our group has developed the non-invasive electrical impedance tomography ( EIT ). The purposes of this study were to estimate the electrical conductivity of localized tissues by non-invasive measurement of the electrical impedance tomography ( EIT ) on localized tissues. This EIT methods has a possibility of early detection of breast cancer and can be used for young women breast cancers which are difficult to be found by mammography because of dense breasts. In this conference, we illustrate our new theory of non-invasive measurement of EIT. Our group ( Department of Surgery of The University of Tokushima and Institute of Technology and Science of The University of Tokushima ) has studied and developed EIT since 1980s and has experimented with non-invasive measurement of EIT since 2000s. A new impedance analytical system was developed, and measurements were performed over a frequency range of 0-100kHz by the four-electrode method. The biological tissue can be regarded electrically as an equivalent consisting of extracellular resistance ( Re ), intracellular resistance ( Ri ), and electrical capacitance of the cell membrane ( Cm ). These three parameter were calculated from the measured values of electrical bio-impedance by the curve-fitting technique using a computer program. It was found that Re and Ri of breast cancers were significantly lower than those of benign tumors, and that Cm of breast cancers was significantly lower than that of benign tumors. Ito Laboratory, Department of Medical System Engineering at Chiba University developed an organism equivalence phantom. Our group used the phantom and made one-layer phantom ( muscle or brain ) and two-layers phantom ( muscle and brain ). Our group measured the electrical conductivity of these one layer and two layers phantoms by our non-invasive measurement of EIT. One-layer phantom was measured by our non-invasive measurement of EIT. The errs of impedance between measured by our new EIT and by ordinary method were whthin 5 %. These results were satisfactorily and proved that one-layer muscle or brain could be measured correctly by our new measurement . But two-layers ( muscle and brain ) phantom was measured by our non-invasive measurement of EIT, the errs of impedance were over 20%. These results were unsatisfactorily. These results suggest that one layer tissues of muscle or brain can be diagnosed by our non-invasive measurement of EIT. Now we are making an improved two layers phantome which are muscle and fat tissue and measure these impedances. If we will be able to a make multi- layers phantom and measure these impedances correctly, our new method will be used by early breast cancer screening.
局部组织电阻抗断层成像(EIT)无创测量诊断新模式的基础研究
用于医学诊断的生物组织信息通常可以通过x射线图像、超声图像和MRI提供,这些图像基本上提供了质量或质子密度分布的信息。另一方面,电生物阻抗包含与组织结构及其生理状态和功能相关的不同信息。众所周知,生物组织的电学性质因其结构的不同而有很大的不同。研究人员在研究肿瘤电特性差异在临床方面的应用时报道了这一点。弗林克和莫尔斯研究了乳腺恶性肿瘤的电学性质。他们发现,与正常或非恶性组织相比,肿瘤组织在20 kHz时的通透性明显更高。其他几项调查也报告了类似的结果。本课题组采用针电极直接测量乳腺良性肿瘤和恶性肿瘤的电阻抗。本课题组开发了无创电阻抗断层扫描技术(EIT)。本研究的目的是通过对局部组织进行电阻抗断层扫描(EIT)的无创测量来估计局部组织的电导率。这种EIT方法有可能早期发现乳腺癌,可用于由于乳房致密而难以通过乳房x光检查发现的年轻妇女乳腺癌。在这次会议上,我们阐述了我们的无创测量EIT的新理论。我们小组(德岛大学外科学系和德岛大学技术与科学研究所)从20世纪80年代开始研究和开发EIT,并从2000年代开始进行EIT的无创测量实验。开发了一种新的阻抗分析系统,并采用四电极法在0-100kHz的频率范围内进行了测量。生物组织可以被看作是由细胞外电阻(Re)、细胞内电阻(Ri)和细胞膜电容(Cm)组成的等价物。这三个参数是利用计算机程序从电生物阻抗的测量值出发,采用曲线拟合的方法计算出来的。发现乳腺癌的Re和Ri明显低于良性肿瘤,乳腺癌的Cm明显低于良性肿瘤。千叶大学医疗系统工程系伊藤实验室研制了一种生物等效体。我们组采用假体制作一层假体(肌肉或大脑)和两层假体(肌肉和大脑)。本课题组采用非侵入式电阻抗测量方法测量了单层和双层模型的电导率。我们采用无创EIT测量方法测量单层幻膜。该方法测量的阻抗与普通方法测量的阻抗误差在5%以内。这些结果令人满意,证明了我们的新测量方法可以正确测量单层肌肉或大脑。而采用非侵入式电阻抗测量法测量两层(肌肉和大脑)的电阻抗时,阻抗误差均在20%以上。这些结果并不令人满意。这些结果表明,我们的无创测量EIT可以诊断肌肉或大脑的单层组织。现在我们正在做一个改进的两层幻体,由肌肉和脂肪组织组成,并测量这些阻抗。如果我们能够制作多层假体并正确测量这些阻抗,我们的新方法将用于早期乳腺癌筛查。
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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