剂量测定器引导的在线自适应前列腺 SBRT 患者质量保证经验。

IF 1.3 Q3 RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING

Journal of Medical Imaging and Radiation Sciences Pub Date : 2024-07-30 DOI:10.1016/j.jmir.2024.101719

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引用次数: 0

摘要

简介本研究旨在评估剂量测定师对在线自适应前列腺 SBRT 治疗计划进行局部治疗前验证的结果方法和材料：我们科室使用我们小组开发和验证的在线自适应方法制定前列腺 SBRT 治疗计划。自适应计划使用瓦里安 Eclipse 治疗计划系统的 Acuros XB v. 16.1 算法在每天的 CBCT 扫描上计算。自适应计划包括在瓦里安TrueBeam直列加速器上使用6 MV无扁平化滤波（FFF）能量进行单次VMAT。使用 Mobius 3D v. 3.1 二次剂量计算程序 (M3D) 对每次治疗中创建的自适应 "每日计划"(POD) 进行治疗前验证。M3D 的调试包括剂量测定叶间隙校正（DLGc）参数的调整。然后使用一组典型部位（前列腺、头颈部、脑、肺和骨姑息）的计划得出通用和特定的 DLGc 值，并为特定的在线 SBRT POD 确定另一组 DLGc 值（分别为 gDLGc 和 sDLGc）。本研究纳入了采用 PACE-B 计划（5 × 7.25 Gy）治疗的前 50 名前列腺患者，即收集了 250 个自适应 SBRT POD。在每个在线自适应 POD 中，对患者 CBCT 中的 Eclipse 3D 剂量和 M3D 剂量进行了全局 3D 伽马比较。以 5% 全局/3 毫米为标准，记录患者整个体外轮廓（Body）和 PTV 的伽马通过率（GPRs）。此外，还分析了 Eclipse 和 M3D 剂量之间的目标平均剂量和目标覆盖率差异（分别为 ΔDmean 和 ΔD90%）。根据 PRIMO Monte Carlo 软件评估了 M3D 的准确性。从 250 个自适应计划中随机选取 25 个在线前列腺 SBRT POD，用 PRIMO 进行模拟：结果：最佳 gDLGc 和 sDLGc 值分别为-1 毫米和-0.14 毫米。在 250 个在线自适应 POD 中，无论使用哪种 DLGc，体部和 PTV 结构的 GPR 值都达到了 100%。使用 sDLGc 而不是 gDLGc 可以获得更好的 ΔDmean （0.1 % ± 0.5% vs. -1.9 ± 0.7 %）和 ΔD90 % （-1.0 % ± 0.5 %. vs. -3.5 % ± 0.8 %）结果。在将 M3D 计算与 PRIMO 模拟进行比较时，也发现了这一问题：结论：M3D 可有效用于在线自适应前列腺 SBRT 计划的独立治疗前验证。建议这种 SBRT 在线自适应技术使用特定的 DLGc 值。

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Experience with patient-specific quality assurance of dosimetrist-led online adaptive prostate SBRT

Introduction

The aim of this study was to assess the results of the local pre-treatment verifications of online adaptive prostate SBRT plans performed by dosimetrists

Methods and Materials

Prostate SBRT treatments are planned in our department using an online adaptive method developed and validated by our group. The adaptive plans were computed on the daily CBCT scan using the Acuros XB v. 16.1 algorithm of the Varian Eclipse treatment planning system. Adaptive plans consisted of a single VMAT with 6 MV flattening-filter-free (FFF) energy performed on a Varian TrueBeam linac. Pre-treatment verification of the adaptive “plan-of-the-day” (POD) created in each treatment session was performed using the Mobius 3D v. 3.1 secondary dose calculation program (M3D). Commissioning of M3D included the tuning of the dosimetric leaf gap correction (DLGc) parameter. Generic and specific DLGc values were then derived using a set of plans for typical sites (prostate, head and neck, brain, lung and bone palliative) and another set were determined for specific online SBRT PODs (gDLGc and sDLGc, respectively). The first 50 prostate patients treated with the PACE-B schedule (5 × 7.25 Gy) were included, i.e., 250 adaptive SBRT PODs were collected in this study. For each online adaptive POD, a global 3D gamma comparison between the Eclipse 3D dose and the M3D dose in the patient CBCT was performed. Gamma passing rates (GPRs) for the whole external patient contour (Body) and the PTV were recorded, using the 5 % global /3 mm criteria. The target mean dose and target coverage differences between the Eclipse and M3D doses were also analyzed (ΔDmean and ΔD90 %, respectively). The accuracy of M3D was assessed against PRIMO Monte Carlo software. Twenty-five online prostate SBRT PODs were randomly selected from the set of 250 adaptive plans and simulated with PRIMO.

Results

Values of -1 mm and -0.14 mm were found as optimal gDLGc and sDLGc, respectively. Over the 250 online adaptive PODs, excellent GPR values ∼ 100 % were obtained for the Body and PTV structures, regardless the type of DLGc used. The use of the sDLGc instead of the gDLGc provided better results for ΔDmean (0.1 % ± 0.5% vs. -1.9 ± 0.7 %) and ΔD90 % (-1.0 % ± 0.5 %. vs. -3.5 % ± 0.8 %). This issue was also observed when M3D calculations were compared to PRIMO simulations.

Conclusions

M3D can be effectively used for independent pre-treatment verifications of online adaptive prostate SBRT plans. The use of a specific DLGc value is advised for this SBRT online adaptive technique.

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来源期刊

Journal of Medical Imaging and Radiation Sciences RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING-

CiteScore

2.30

自引率

11.10%

发文量

231

审稿时长

53 days

期刊介绍： Journal of Medical Imaging and Radiation Sciences is the official peer-reviewed journal of the Canadian Association of Medical Radiation Technologists. This journal is published four times a year and is circulated to approximately 11,000 medical radiation technologists, libraries and radiology departments throughout Canada, the United States and overseas. The Journal publishes articles on recent research, new technology and techniques, professional practices, technologists viewpoints as well as relevant book reviews.