MR compatible detectors assessment for a 0.35 T MR-linac commissioning.

IF 3.3 2区医学 Q2 ONCOLOGY

Radiation Oncology Pub Date : 2024-03-20 DOI:10.1186/s13014-024-02431-8

Michel Chea, Mathilde Croisé, Christelle Huet, Céline Bassinet, Mohamed-Amine Benadjaoud, Catherine Jenny

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Abstract

Purpose: To assess a large panel of MR compatible detectors on the full range of measurements required for a 0.35 T MR-linac commissioning by using a specific statistical method represented as a continuum of comparison with the Monte Carlo (MC) TPS calculations. This study also describes the commissioning tests and the secondary MC dose calculation validation.

Material and methods: Plans were created on the Viewray TPS to generate MC reference data. Absolute dose points, PDD, profiles and output factors were extracted and compared to measurements performed with ten different detectors: PTW 31010, 31021, 31022, Markus 34045 and Exradin A28 MR ionization chambers, SN Edge shielded diode, PTW 60019 microdiamond, PTW 60023 unshielded diode, EBT3 radiochromic films and LiF µcubes. Three commissioning steps consisted in comparison between calculated and measured dose: the beam model validation, the output calibration verification in four different phantoms and the commissioning tests recommended by the IAEA-TECDOC-1583.

Main results: The symmetry for the high resolution detectors was higher than the TPS data of about 1%. The angular responses of the PTW 60023 and the SN Edge were - 6.6 and - 11.9% compared to the PTW 31010 at 60°. The X/Y-left and the Y-right penumbras measured by the high resolution detectors were in good agreement with the TPS values except for the PTW 60023 for large field sizes. For the 0.84 × 0.83 cm² field size, the mean deviation to the TPS of the uncorrected OF was - 1.7 ± 1.6% against - 4.0 ± 0.6% for the corrected OF whereas we found - 4.8 ± 0.8% for passive dosimeters. The mean absolute dose deviations to the TPS in different phantoms were 0 ± 0.4%, - 1.2 ± 0.6% and 0.5 ± 1.1% for the PTW 31010, PTW 31021 and Exradin A28 MR respectively.

Conclusions: The magnetic field effects on the measurements are considerably reduced at low magnetic field. The PTW 31010 ionization chamber can be used with confidence in different phantoms for commissioning and QA tests requiring absolute dose verifications. For relative measurements, the PTW 60019 presented the best agreement for the full range of field size. For the profile assessment, shielded diodes had a behaviour similar to the PTW 60019 and 60023 while the ionization chambers were the most suitable detectors for the symmetry. The output correction factors published by the IAEA TRS 483 seem to be applicable at low magnetic field pending the publication of new MR specific values.

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对 0.35 T MR-linac 调试的 MR 兼容探测器进行评估。

目的：使用一种特定的统计方法，通过与蒙特卡洛（MC）TPS 计算的连续比较，评估一大批磁共振兼容探测器在 0.35 T 磁共振线性调试中所需的全方位测量。本研究还介绍了调试测试和二次 MC 剂量计算验证：在 Viewray TPS 上创建计划，生成 MC 参考数据。提取绝对剂量点、PDD、剖面和输出因子，并与使用十种不同探测器进行的测量结果进行比较：这些探测器包括：PTW 31010、31021、31022、Markus 34045 和 Exradin A28 MR 电离室、SN Edge 屏蔽二极管、PTW 60019 微钻石、PTW 60023 非屏蔽二极管、EBT3 放射性变色薄膜和 LiF µ 立方体。三个调试步骤包括对计算剂量和测量剂量进行比较：光束模型验证、在四个不同模型中进行输出校准验证以及进行 IAEA-TECDOC-1583 建议的调试测试：高分辨率探测器的对称性比 TPS 数据高出约 1%。与 PTW 31010 相比，PTW 60023 和 SN Edge 在 60° 时的角度响应分别为-6.6%和-11.9%。高分辨率探测器测得的 X/Y 左半影和 Y 右半影与 TPS 值十分吻合，但 PTW 60023 在大场尺寸时除外。对于 0.84 × 0.83 平方厘米的磁场尺寸，未校正 OF 与 TPS 的平均偏差为 - 1.7 ± 1.6%，而校正 OF 为 - 4.0 ± 0.6%，而我们发现被动剂量计为 - 4.8 ± 0.8%。PTW 31010、PTW 31021 和 Exradin A28 MR 在不同模型中的 TPS 平均绝对剂量偏差分别为 0 ± 0.4%、- 1.2 ± 0.6% 和 0.5 ± 1.1%：在低磁场条件下，磁场对测量的影响大大降低。PTW 31010 电离室可在不同的模型中放心使用，用于需要绝对剂量验证的调试和质量保证测试。对于相对测量，PTW 60019 在整个磁场大小范围内的一致性最好。在剖面评估方面，屏蔽二极管的表现与 PTW 60019 和 60023 相似，而电离室则是最适合对称性测量的探测器。国际原子能机构 TRS 483 公布的输出校正系数似乎适用于低磁场，但有待公布新的磁共振特定值。

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

Radiation Oncology ONCOLOGY-RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING

CiteScore

6.50

自引率

2.80%

发文量

181

审稿时长

3-6 weeks

期刊介绍： Radiation Oncology encompasses all aspects of research that impacts on the treatment of cancer using radiation. It publishes findings in molecular and cellular radiation biology, radiation physics, radiation technology, and clinical oncology.

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