基于GPU的1.5T MR-LINAC蒙特卡罗剂量验证模块及软件的开发与临床应用
Development and clinical application of a GPU-based Monte Carlo dose verification module and software for 1.5 T MR-LINAC.
作者信息
Cheng Bo, Xu Yuan, Li Shijun, Ren Qiang, Pei Xi, Men Kuo, Dai Jianrong, Xu Xie George
机构信息
School of Nuclear Science and Technology, University of Science and Technology of China, Hefei, China.
Department of Radiation Oncology, National Cancer Center/National Clinical Research Center for Cancer/Cancer Hospital, Chinese Academy of Medical Sciences and Peking Union Medical College, Beijing, China.
出版信息
Med Phys. 2023 May;50(5):3172-3183. doi: 10.1002/mp.16337. Epub 2023 Mar 14.
BACKGROUND
Adaptive radiotherapy (ART) has made significant advances owing to magnetic resonance linear accelerator (MR-LINAC), which provides superior soft-tissue contrast, fast speed and rich functional magnetic resonance imaging (MRI) to guide radiotherapy. Independent dose verification plays a critical role in discovering errors, while several challenges remain in MR-LINAC.
PURPOSE
A Monte Carlo-based GPU-accelerated dose verification module for Unity is proposed and integrated into the commercial software ArcherQA to achieve fast and accurate quality assurance (QA) for online ART.
METHODS
Electron or positron motion in a magnetic field was implemented, and a material-dependent step-length limit method was used to trade off speed and accuracy. Transport was verified by dose comparison with EGSnrc in three A-B-A phantoms. Then, an accurate Monte Carlo-based Unity machine model was built in ArcherQA, including an MR-LINAC head, cryostat, coils, and treatment couch. In particular, a mixed model combining measured attenuation and homogeneous geometry was adopted for the cryostat. Several parameters in the LINAC model were tuned to commission it in the water tank. An alternating open-closed MLC plan on solid water measured with EBT-XD film was used to verify the LINAC model. Finally, the ArcherQA dose was compared with ArcCHECK measurements and GPUMCD in 30 clinical cases through the gamma test.
RESULTS
ArcherQA and EGSnrc were well matched in three A-B-A phantom tests, and the relative dose difference (RDD) was less than 1.6% in the homogenous region. A Unity model was commissioned in the water tank, and the RDD in the homogenous region was less than 2%. In the alternating open-closed MLC plan, the gamma result (3%/3 mm) between ArcherQA and Film was 96.55%, better than the gamma result between GPUMCD and Film (92.13%). In 30 clinical cases, the mean three-dimensional (3D) gamma result (3%/2 mm) was 99.36% ± 1.28% between ArcherQA and ArcCHECK for the QA plans and 99.27% ± 1.04% between ArcherQA and GPUMCD for the clinical patient plans. The average dose calculation time was 106 s in all clinical patient plans.
CONCLUSIONS
A GPU-accelerated Monte Carlo-based dose verification module was developed and built for the Unity MR-LINAC. The fast speed and high accuracy were proven by comparison with EGSnrc, commission data, the ArcCHECK measurement dose, and the GPUMCD dose. This module can achieve fast and accurate independent dose verification for Unity.
背景
自适应放射治疗(ART)由于磁共振直线加速器(MR-LINAC)取得了重大进展,该加速器提供了卓越的软组织对比度、快速速度以及丰富的功能磁共振成像(MRI)以指导放射治疗。独立剂量验证在发现误差方面起着关键作用,而MR-LINAC仍存在一些挑战。
目的
提出并将基于蒙特卡罗的GPU加速剂量验证模块集成到商业软件ArcherQA中,以实现在线ART的快速准确质量保证(QA)。
方法
实现了电子或正电子在磁场中的运动,并采用了基于材料的步长限制方法来平衡速度和准确性。通过在三个A-B-A体模中与EGSnrc进行剂量比较来验证传输。然后,在ArcherQA中建立了基于蒙特卡罗的精确Unity机器模型,包括MR-LINAC机头、低温恒温器、线圈和治疗床。特别地,对低温恒温器采用了结合测量衰减和均匀几何形状的混合模型。调整了LINAC模型中的几个参数以在水箱中进行调试。使用用EBT-XD胶片测量的固体水上的交替开闭MLC计划来验证LINAC模型。最后,通过伽马测试将ArcherQA剂量与30例临床病例中的ArcCHECK测量值和GPUMCD进行比较。
结果
在三个A-B-A体模测试中,ArcherQA与EGSnrc匹配良好,均匀区域内的相对剂量差异(RDD)小于1.6%。在水箱中对Unity模型进行了调试,均匀区域内的RDD小于2%。在交替开闭MLC计划中,ArcherQA与胶片之间的伽马结果(3%/3mm)为96.55%,优于GPUMCD与胶片之间的伽马结果(92.13%)。在30例临床病例中,QA计划的ArcherQA与ArcCHECK之间的平均三维(3D)伽马结果(3%/2mm)为99.36%±1.28%,临床患者计划的ArcherQA与GPUMCD之间的平均三维伽马结果为99.27%±1.04%。所有临床患者计划的平均剂量计算时间为106秒。
结论
为Unity MR-LINAC开发并构建了基于GPU加速的蒙特卡罗剂量验证模块。通过与EGSnrc、调试数据、ArcCHECK测量剂量和GPUMCD剂量的比较,证明了其快速性和高精度。该模块可以实现对Unity的快速准确独立剂量验证。
Zotero 插件