开发用于评估四维计算机断层扫描的新型 3D 打印动态拟人胸廓模型

IF 3.4 Q2 ONCOLOGY
Didier Lustermans , Roua Abdulrahim , Vicki Trier Taasti , Juliane Szkitsak , Evita Švėgždaitė , Sarina Clarkin , Brigitte Reniers , Frank Verhaegen , Gabriel Paiva Fonseca
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引用次数: 0

摘要

背景和目的在放射治疗中,四维计算机断层扫描(4DCT)的图像质量经常会因呼吸不规则造成的伪影而下降。质量保证大多采用简单的模型,不能完全反映患者的复杂性和动态性。三维打印技术允许设计高度定制化的模型。本研究旨在验证逼真的动态胸腔模型及其 4DCT 应用的概念验证。材料和方法利用三维打印技术,用组织等效材料制作了逼真的胸腔模型,包括软组织、骨骼和可压缩肺部(包括支气管和肿瘤)。肺部压缩可通过电机模拟定制的呼吸曲线来实现,并为监测系统的应用增加了一个平台。该模型包含三个肿瘤,根据肿瘤运动幅度对其进行评估。为了评估重现性,对不同肺压缩程度的三个 4DCT 序列和重复静态图像进行了采集。结果该模型显示,静态 3DCT 图像和 4DCT 图像在所有方向上的重现性分别为 ±0.2 毫米和 ±0.4 毫米。此外,靠近膈肌的肿瘤在下/上方向的振幅(13.9 毫米)高于在肺部较高位置的病灶(8.1 毫米),正如在患者身上观察到的那样。更复杂的呼吸模式显示了常见的 4DCT 伪影。该模型代表了逼真的解剖结构,对其进行 4DCT 扫描可产生逼真的伪影,从而有利于 4DCT 质量保证或方案优化。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Development of a novel 3D-printed dynamic anthropomorphic thorax phantom for evaluation of four-dimensional computed tomography

Background and purpose

In radiotherapy, the image quality of four-dimensional computed tomography (4DCT) is often degraded by artifacts resulting from breathing irregularities. Quality assurance mostly employ simplistic phantoms, not fully representing complexities and dynamics in patients. 3D-printing allows for design of highly customized phantoms. This study aims to validate the proof-of-concept of a realistic dynamic thorax phantom and its 4DCT application.

Materials and methods

Using 3D-printing, a realistic thorax phantom was produced with tissue-equivalent materials for soft tissue, bone, and compressible lungs, including bronchi and tumors. Lung compression was facilitated by motors simulating customized breathing curves with an added platform for application of monitoring systems. The phantom contained three tumors which were assessed in terms of tumor motion amplitude. Three 4DCT sequences and repeated static images for different lung compression levels were acquired to evaluate the reproducibility. Moreover, more complex patient-specific breathing patterns with irregularities were simulated.

Results

The phantom showed a reproducibility of ±0.2 mm and ±0.4 mm in all directions for static 3DCT images and 4DCT images, respectively. Furthermore, the tumor close to the diaphragm showed higher amplitudes in the inferior/superior direction (13.9 mm) than lesions higher in the lungs (8.1 mm) as observed in patients. The more complex breathing patterns demonstrated commonly seen 4DCT artifacts.

Conclusion

This study developed a dynamic 3D-printed thorax phantom, which simulated customized breathing patterns. The phantom represented a realistic anatomy and 4DCT scanning of it could create realistic artifacts, making it beneficial for 4DCT quality assurance or protocol optimization.
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来源期刊
Physics and Imaging in Radiation Oncology
Physics and Imaging in Radiation Oncology Physics and Astronomy-Radiation
CiteScore
5.30
自引率
18.90%
发文量
93
审稿时长
6 weeks
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