肺肿瘤 Ethos 适应性治疗的可行性及相关质量保证。

Feasibility of Ethos adaptive treatments of lung tumors and associated quality assurance.

机构信息

Department of Radiotherapy and Radiation Oncology, University of Wurzburg, Wurzburg, Germany.

出版信息

J Appl Clin Med Phys. 2024 Jul;25(7):e14311. doi: 10.1002/acm2.14311. Epub 2024 Feb 22.

DOI:10.1002/acm2.14311

PMID:38386919

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11244680/

Abstract

MOTIVATION

Online adaptive radiotherapy with Ethos is based on the anatomy determined from daily cone beam computed tomography (CBCT) images. Dose optimization and computation are performed on the density map of a synthetic CT (sCT), a deformable registration of the initial planning CT (pCT) onto the current CBCT. Large density changes as present in the lung region are challenging the system.

METHODS

Treatment plans for Ethos were created and delivered for 1, 2, and 3 cm diameter lung lesions in an anthropomorphic phantom, combining different insets in the pCT and during adaptive and non-adaptive treatment sessions. Primary and secondary dose calculations as well as back-projected dose from portal images were evaluated.

RESULTS

Density changes due to changed insets were not considered in the sCTs. This resulted in errors in the dose; for example, -15.9% of the mean dose for a plan when changing from a 3 cm inset in the pCT to 1 cm at the time of treatment. Secondary dose calculation is based on the sCT and could therefore not reveal these dose errors. However, dose calculation on the CBCT, either as a recalculation in the treatment planning system or as pre-treatment quality assurance (QA) before the treatment, indicated the differences. EPID in-vivo QA also reported discrepancies between calculated and delivered dose distributions.

CONCLUSIONS

An incorrect density distribution in the sCT has an impact on the dose calculation accuracy in the adaptive treatment workflow with the Ethos system. Additional quality checks of the sCT can detect such errors.

摘要

动机

Ethos 的在线自适应放射治疗基于从日常锥形束计算机断层扫描 (CBCT) 图像确定的解剖结构。密度图上的剂量优化和计算在合成 CT（sCT）上进行，sCT 是初始计划 CT（pCT）到当前 CBCT 的可变形配准。肺区存在的大密度变化对系统提出了挑战。

方法

为人体模型中的 1、2 和 3 厘米直径的肺病变创建了 Ethos 的治疗计划，并在自适应和非自适应治疗过程中结合 pCT 和自适应治疗过程中的不同窗宽进行了治疗。评估了初级和次级剂量计算以及来自门控图像的反向投影剂量。

结果

sCT 中未考虑由于不同窗宽导致的密度变化。这导致剂量出现误差；例如，当治疗时 pCT 中的 3 厘米窗宽改为 1 厘米时，计划的平均剂量降低了 15.9%。二级剂量计算基于 sCT，因此无法发现这些剂量误差。然而，在治疗计划系统中重新计算或在治疗前进行预治疗质量保证 (QA) 的 CBCT 上的剂量计算可以指示这些差异。Epid 体内 QA 也报告了计算剂量分布和实际剂量分布之间的差异。

结论

Ethos 系统自适应治疗工作流程中，sCT 中不正确的密度分布会影响剂量计算的准确性。对 sCT 进行额外的质量检查可以检测到这些错误。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/a5f0/11244680/84e03901a83b/ACM2-25-e14311-g004.jpg

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肺肿瘤 Ethos 适应性治疗的可行性及相关质量保证。

Feasibility of Ethos adaptive treatments of lung tumors and associated quality assurance.

机构信息

Department of Radiotherapy and Radiation Oncology, University of Wurzburg, Wurzburg, Germany.