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使用三轴天线进行微波消融:牛肝脏离体实验结果

Microwave Ablation With a Triaxial Antenna: Results in ex vivo Bovine Liver.

作者信息

Brace Christopher L, Laeseke Paul F, van der Weide Daniel W, Lee Fred T

机构信息

Electrical and Computer Engineering Department, University of Wisconsin-Madison, Madison, WI 53706 USA (e-mail:

出版信息

IEEE Trans Microw Theory Tech. 2005 Jan;53(1):215-220. doi: 10.1109/TMTT.2004.839308.

DOI:10.1109/TMTT.2004.839308
PMID:18079981
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2134893/
Abstract

We apply a new triaxial antenna for microwave ablation procedures to an ex vivo bovine liver. The antenna consists of a coaxial monopole inserted through a biopsy needle positioned one quarter-wavelength from the antenna base. The insertion needle creates a triaxial structure, which enhances return loss more than 10 dB, maximizing energy transfer to the tissue while minimizing feed cable heating and invasiveness. Numerical electromagnetic and thermal simulations are used to optimize the antenna design and predict heating patterns. Numerical and ex vivo experimental results show that the lesion size depends strongly on ablation time and average input power, but not on peak power. Pulsing algorithms are also explored. We were able to measure a 3.8-cm lesion using 50 W for 7 min, which we believe to be the largest lesion reported thus far using a 17-gauge insertion needle.

摘要

我们将一种用于微波消融手术的新型三轴天线应用于离体牛肝。该天线由一根同轴单极子组成,它通过一根活检针插入,活检针位于距天线基部四分之一波长处。插入针形成了一种三轴结构,可将回波损耗提高超过10 dB,在使馈电电缆发热和侵入性最小化的同时,将能量传输至组织的效率最大化。利用数值电磁和热模拟来优化天线设计并预测加热模式。数值和离体实验结果表明,病变大小在很大程度上取决于消融时间和平均输入功率,而不取决于峰值功率。还探索了脉冲算法。我们能够使用50 W功率持续7分钟测量出一个3.8厘米的病变,我们认为这是迄今为止使用17号插入针所报道的最大病变。

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