钨填充 3D 打印适形设备用于电子束放射治疗。

Tungsten filled 3D printed field shaping devices for electron beam radiation therapy.

机构信息

Department of Radiation Oncology, Stanford University, Palo Alto, CA, United States of America.

出版信息

PLoS One. 2019 Jun 19;14(6):e0217757. doi: 10.1371/journal.pone.0217757. eCollection 2019.

DOI:10.1371/journal.pone.0217757

PMID:31216296

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6584017/

Abstract

PURPOSE

Electron radiotherapy is a labor-intensive treatment option that is complicated by the need for field shaping blocks. These blocks are typically made from casting Cerrobend alloys containing lead and cadmium. This is a highly toxic process with limited precision. This work aims to provide streamlined and more precise electron radiotherapy by 3D using printing techniques.

METHODS

The 3D printed electron cutout consists of plastic shells filled with 2 mm diameter tungsten ball bearings. Five clinical Cerrobend defined field were compared to the planned fields by measuring the light field edge when mounted in the electron applicator on a linear accelerator. The dose transmitted through the 3D printed and Cerrobend cutouts was measured using an IC profiler ion chamber array with 6 MeV and 16 MeV beams. Dose profiles from the treatment planning system were also compared to the measured dose profiles. Centering and full width half maximum (FWHM) metrics were taken directly from the profiler software.

RESULTS

The transmission of a 16MeV beam through a 12 mm thick layer of tungsten ball bearings agreed within 1% of a 15 mm thick Cerrobend block (measured with an ion chamber array). The radiation fields shaped by ball bearing filled 3D printed cutout were centered within 0.4 mm of the planned outline, whereas the Cerrobend cutout fields had shift errors of 1-3 mm, and shape errors of 0.5-2 mm. The average shift of Cerrobend cutouts was 2.3 mm compared to the planned fields (n = 5). Beam penumbra of the 3D printed cutouts was found to be equivalent to the 15 mm thick Cerrobend cutout. The beam profiles agreed within 1.2% across the whole 30 cm profile widths.

CONCLUSIONS

This study demonstrates that with a proper quality assurance procedure, 3D-printed cutouts can provide more accurate electron radiotherapy with reduced toxicity compared to traditional Cerrobend methods.

摘要

目的

电子放射治疗是一种劳动密集型的治疗选择，需要使用场成型块，这使得治疗过程变得复杂。这些成型块通常由铸造 Cerrobend 合金制成，其中含有铅和镉。这是一个高度有毒的过程，精度有限。本研究旨在通过 3D 打印技术提供更精简、更精确的电子放射治疗。

方法

3D 打印的电子切出物由填充有 2 毫米直径钨球轴承的塑料外壳组成。将五个临床 Cerrobend 定义的场与计划场进行比较，方法是将其安装在电子适形器上时测量光场边缘在直线加速器上。使用具有 6 MeV 和 16 MeV 束的 IC 轮廓电离室阵列测量通过 3D 打印和 Cerrobend 切出物传输的剂量。还将治疗计划系统的剂量分布与测量的剂量分布进行了比较。中心位置和半高全宽（FWHM）指标直接从轮廓仪软件中获取。

结果

16 MeV 束穿过 12 毫米厚的钨球轴承层的传输与 15 毫米厚的 Cerrobend 块（用电离室阵列测量）一致，误差在 1%以内。由充满球轴承的 3D 打印切出物形成的辐射场的中心位置在计划轮廓的 0.4 毫米内，而 Cerrobend 切出物的场则有 1-3 毫米的移位误差和 0.5-2 毫米的形状误差。与计划场相比，Cerrobend 切出物的平均移位为 2.3 毫米（n=5）。发现 3D 打印切出物的束半影与 15 毫米厚的 Cerrobend 切出物相当。整个 30 厘米轮廓宽度的光束分布在 1.2%以内一致。

结论

本研究表明，通过适当的质量保证程序，3D 打印切出物可以提供比传统 Cerrobend 方法更准确的电子放射治疗，同时减少毒性。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/df7b/6584017/8d3ce115309c/pone.0217757.g001.jpg

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钨填充 3D 打印适形设备用于电子束放射治疗。

Tungsten filled 3D printed field shaping devices for electron beam radiation therapy.

机构信息

出版信息

PURPOSE

METHODS

RESULTS

CONCLUSIONS

目的

方法

结果

结论

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