Computational modeling of microwave ablation of lung tumors: Assessment of model-predictions against post-treatment imaging

IF 3.2 2区医学 Q1 RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING

Medical physics Pub Date : 2025-05-22 DOI:10.1002/mp.17897

Jan Sebek, Pinyo Taeprasartsit, Chanok Pathomparai, Damian E. Dupuy, Henky Wibowo, Punit Prakash

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引用次数: 0

Abstract

Background

Percutaneous microwave ablation is a clinically established method for treatment of unresectable lung nodules. When planning the intervention, the size of ablation zone, which should encompass the nodule as well as a surrounding margin of normal tissue, is predicted via manufacturer-provided geometric models, which do not consider patient-specific characteristics. However, the size and shape of ablation is dependent on tissue composition and properties and can vary between patients.

Purpose

To comparatively assess performance of a computational model-based approach and manufacturer geometric model for predicting extent of ablation zones following microwave lung ablation procedures on a retrospectively collected clinical imaging dataset.

Methods

A retrospective computed-tomography (CT) imaging dataset was assembled of 50 patients treated with microwave ablation of lung tumors at a single institution. For each case, the dataset consisted of a pre-procedure CT acquired without the ablation applicator, a peri-procedure CT scan with the ablation applicator in position, and post-procedure CT scan to assess the ablation zone extent acquired on the first follow-up visit. A physics-based computational model of microwave absorption and bioheat transfer was implemented using the finite element method, with the model geometry incorporating key tissue types within 2 cm of the applicator as informed by imaging data. The model-predicted extent of the ablation zone was estimated using the Arrhenius thermal damage model. The ablation zone predicted by the manufacturer geometric model consisted of an ellipsoid registered with the applicator position and dimensions provided by instructions for use documentation. Both ablation estimates were compared to ground truth ablation zone segmented from post-procedure CT via Dice similarity coefficient (DSC) and average absolute error (AAE). The statistically significant difference at level 0.05 in performance between both ablation prediction methods was tested with permutation test on DSC as well as AAE datasets with applied Bonferroni multiple-comparison correction.

Results

Receiver operating characteristic analysis of the predictive power of the volume of insufficient coverage (i.e. tumor volume which did not receive an ablative thermal dose) as an indicator of local tumor recurrence yielded an area under the curve of 0.84, illustrating the clinical significance of accurate prediction of ablation zone extents. Across all cases, AAEs were 3.65 ± 1.12 mm, and 5.11 ± 1.93 mm for patient-specific computational and manufacturer geometric models respectively. Similarly, average DSCs were 0.55 ± 0.14, and 0.46 ± 0.19 for computational and manufacturer geometric models respectively. The manufacturer geometric model overpredicted volume of the ablation zone compared to ground truth by 141% on average, whereas the patient-specific computational model overpredicted ablation zone volumes by 31.5% on average.

Conclusions

Patient-specific physics-based computational models of lung microwave ablation yield improved prediction of microwave ablation extent compared to the manufacturer geometric model.

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肺肿瘤微波消融的计算建模：模型预测对治疗后影像学的评估。

背景：经皮微波消融是一种临床公认的治疗不可切除肺结节的方法。当计划干预时，消融区的大小应该包括结节以及正常组织的周围边缘，通过制造商提供的几何模型来预测，而不考虑患者的具体特征。然而，消融的大小和形状取决于组织组成和性质，并可能因患者而异。目的：在回顾性收集的临床影像数据集上，比较评估基于计算模型的方法和制造商几何模型在预测微波肺消融手术后消融区范围方面的性能。方法：回顾性计算机断层扫描（CT）成像数据集汇编了50例在同一机构接受微波消融治疗的肺部肿瘤患者。对于每个病例，数据集包括术前未使用消融器的CT扫描，术中使用消融器的CT扫描，以及术后首次随访时获得的评估消融区范围的CT扫描。使用有限元方法实现了基于物理的微波吸收和生物热传递计算模型，该模型的几何形状包含了成像数据告知的涂抹器2厘米内的关键组织类型。利用Arrhenius热损伤模型对模型预测的烧蚀区范围进行了估算。由制造商几何模型预测的消融区域由一个椭球组成，该椭球与使用说明文件提供的涂抹器位置和尺寸相匹配。通过Dice相似系数（DSC）和平均绝对误差（AAE）将两种消融估计值与术后CT分割的真实消融区进行比较。采用DSC和AAE数据集的排列检验，并应用Bonferroni多重比较校正，对两种消融预测方法的性能进行了0.05水平的统计学差异检验。结果：对未覆盖不足体积（即未接受消融热剂量的肿瘤体积）作为肿瘤局部复发指标的受试者操作特征分析，其预测能力曲线下面积为0.84，说明准确预测消融区范围的临床意义。在所有病例中，患者特异性计算模型和制造商几何模型的ae分别为3.65±1.12 mm和5.11±1.93 mm。同样，计算模型和制造商几何模型的平均dsc分别为0.55±0.14和0.46±0.19。制造商几何模型对消融区体积的预测比实际情况平均高出141%，而针对患者的计算模型对消融区体积的预测平均高出31.5%。结论：与制造商的几何模型相比，基于患者特异性物理的肺部微波消融计算模型可以更好地预测微波消融程度。

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

Medical physics 医学-核医学

CiteScore

6.80

自引率

15.80%

发文量

660

审稿时长

1.7 months

期刊介绍： Medical Physics publishes original, high impact physics, imaging science, and engineering research that advances patient diagnosis and therapy through contributions in 1) Basic science developments with high potential for clinical translation 2) Clinical applications of cutting edge engineering and physics innovations 3) Broadly applicable and innovative clinical physics developments Medical Physics is a journal of global scope and reach. By publishing in Medical Physics your research will reach an international, multidisciplinary audience including practicing medical physicists as well as physics- and engineering based translational scientists. We work closely with authors of promising articles to improve their quality.