Study of a non-water-cooled microwave ablation needle based on a vacuum needle rod to achieve carbonization-free operation: design, simulation, and experimental research.

IF 2 4区医学 Q2 SURGERY

Minimally Invasive Therapy & Allied Technologies Pub Date : 2025-08-16 DOI:10.1080/13645706.2025.2543894

Wei Wei, Chen Li, Weitao Li, Mengwei Jiang, Xiao Zhang, Lidong Xing, Zhiyu Qian, Xiaofei Jin

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引用次数: 0

Abstract

Background: At present, the microwave ablation needle used in clinic needs to add water circulation in the needle rod to reduce the rod temperature. However, the water circulation will take away a lot of heat during the ablation process, which requires increasing the ablation dose to achieve the expected thermal coagulation target volume. This undoubtedly increases the risk of carbonization.

Methods: A design scheme of non-water-cooled microwave ablation needle based on double-layer vacuum structure was proposed. Two types of non-water-cooled microwave ablation needles with long and short needles were designed, and the ablation simulation was carried out by establishing the finite element simulation model.

Results: Simulation and experimental results indicate that, at 20 W power, the long-needle vacuum tube ablation needle can create a carbonization-free solidification zone with a length of 34 mm after 180 s of ablation, whereas the short-needle vacuum tube ablation needle requires 300 s to form a similar zone with a length of 30 mm. Additionally, the axial ratio of the solidification zone created by the long-needle vacuum tube ablation needle exceeds that of the short-needle one. Consequently, the long-needle vacuum tube ablation needle is more apt for creating a larger solidification zone with minimal carbonization, while also achieving a more spherical shape.By comparing the ablation effects of long needle vacuum tube ablation needle and ky-2450b1 under low power,It is verified that the vacuum tube non-water-cooled ablation needle can ensure the effective ablation volume and non carbonization ablation under low-power and short-time ablation, which provides an important technical scheme for clinical optimization of the therapeutic effect of microwave ablation.

Conclusions: The LPH-W-F-MWA is more adept at creating a larger coagulation zone with minimal carbonization, achieving a more spherical shape to a greater extent. This ensures both an effective ablation volume and char-free ablation, offering a crucial technical solution for optimizing the therapeutic effect of MWA in clinical settings.

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基于真空针杆实现无碳化操作的非水冷微波烧蚀针的研究：设计、模拟与实验研究。

背景：目前临床上使用的微波消融针需要在针杆中加入水循环来降低针杆温度。但在烧蚀过程中，水循环会带走大量热量，需要增加烧蚀剂量才能达到预期的热凝靶体积。这无疑增加了碳化的风险。方法：提出一种基于双层真空结构的非水冷微波消融针的设计方案。设计了长针和短针两种非水冷微波烧蚀针，通过建立有限元仿真模型进行烧蚀仿真。结果：模拟和实验结果表明，在20 W功率下，长针真空管烧蚀针在烧蚀180 s后即可形成长度为34 mm的无碳化凝固区，而短针真空管烧蚀针则需要300 s才能形成长度为30 mm的无碳化凝固区。此外，长针真空管烧蚀针形成的凝固区轴比大于短针。因此，长针真空管烧蚀针更倾向于以最小的碳化产生更大的凝固区域，同时也实现更球形的形状。通过对长针真空管消融针与key -2450b1在低功率下的消融效果进行比较，验证了真空管非水冷消融针在低功率短时间消融下能够保证有效的消融体积和非碳化消融，为临床优化微波消融治疗效果提供了重要的技术方案。结论：LPH-W-F-MWA更擅长在最小碳化的情况下形成更大的混凝区，在更大程度上实现更球形。这确保了有效的消融体积和无炭消融，为优化临床MWA的治疗效果提供了关键的技术解决方案。

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

Minimally Invasive Therapy & Allied Technologies 医学-外科

CiteScore

3.80

自引率

5.90%

发文量

审稿时长

6-12 weeks

期刊介绍： Minimally Invasive Therapy and Allied Technologies (MITAT) is an international forum for endoscopic surgeons, interventional radiologists and industrial instrument manufacturers. It is the official journal of the Society for Medical Innovation and Technology (SMIT) whose membership includes representatives from a broad spectrum of medical specialities, instrument manufacturing and research. The journal brings the latest developments and innovations in minimally invasive therapy to its readers. What makes Minimally Invasive Therapy and Allied Technologies unique is that we publish one or two special issues each year, which are devoted to a specific theme. Key topics covered by the journal include: interventional radiology, endoscopic surgery, imaging technology, manipulators and robotics for surgery and education and training for MIS.