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大运动幅度肺部肿瘤质子治疗的计划制定和 4D 稳健性评估策略。

Treatment planning and 4D robust evaluation strategy for proton therapy of lung tumors with large motion amplitude.

机构信息

Department of Radiation Oncology (MAASTRO), GROW - School for Oncology, Maastricht University Medical Centre+, Maastricht, Netherlands.

出版信息

Med Phys. 2021 Aug;48(8):4425-4437. doi: 10.1002/mp.15067. Epub 2021 Jul 17.

DOI:10.1002/mp.15067
PMID:34214201
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8456954/
Abstract

PURPOSE

Intensity-modulated proton therapy (IMPT) for lung tumors with a large tumor movement is challenging due to loss of robustness in the target coverage. Often an upper cut-off at 5-mm tumor movement is used for proton patient selection. In this study, we propose (1) a robust and easily implementable treatment planning strategy for lung tumors with a movement larger than 5 mm, and (2) a four-dimensional computed tomography (4DCT) robust evaluation strategy for evaluating the dose distribution on the breathing phases.

MATERIALS AND METHODS

We created a treatment planning strategy based on the internal target volume (ITV) concept (aim 1). The ITV was created as a union of the clinical target volumes (CTVs) on the eight 4DCT phases. The ITV expanded by 2 mm was the target during robust optimization on the average CT (avgCT). The clinical plan acceptability was judged based on a robust evaluation, computing the voxel-wise min and max (VWmin/max) doses over 28 error scenarios (range and setup errors) on the avgCT. The plans were created in RayStation (RaySearch Laboratories, Stockholm, Sweden) using a Monte Carlo dose engine, commissioned for our Mevion S250i Hyperscan system (Mevion Medical Systems, Littleton, MA, USA). We developed a new 4D robust evaluation approach (4DRobAvg; aim 2). The 28 scenario doses were computed on each individual 4DCT phase. For each scenario, the dose distributions on the individual phases were deformed to the reference phase and combined to a weighted sum, resulting in 28 weighted sum scenario dose distributions. From these 28 scenario doses, VWmin/max doses were computed. This new 4D robust evaluation was compared to two simpler 4D evaluation strategies: re-computing the nominal plan on each individual 4DCT phase (4DNom) and computing the robust VWmin/max doses on each individual phase (4DRobInd). The treatment planning and dose evaluation strategies were evaluated for 16 lung cancer patients with tumor movement of 4-26 mm.

RESULTS

The ratio of the ITV and CTV volumes increased linearly with the tumor amplitude, with an average ratio of 1.4. Despite large ITV volumes, a clinically acceptable plan fulfilling all target and organ at risk (OAR) constraints was feasible for all patients. The 4DNom and 4DRobInd evaluation strategies were found to under- or overestimate the dosimetric effect of the tumor movement, respectively. 4DRobInd showed target underdosage for five patients, not observed in the robust evaluation on the avgCT or in 4DRobAvg. The accuracy of dose deformation used in 4DRobAvg was quantified and found acceptable, with differences for the dose-volume parameters below 1 Gy in most cases.

CONCLUSION

The proposed ITV-based planning strategy on the avgCT was found to be a clinically feasible approach with adequate tumor coverage and no OAR overdosage even for large tumor movement. The new proposed 4D robust evaluation, 4DRobAvg, was shown to give an easily interpretable understanding of the effect of respiratory motion dose distribution, and to give an accurate estimate of the dose delivered in the different breathing phases.

摘要

目的

由于目标覆盖范围的稳健性丧失,对于具有较大肿瘤运动的肺部肿瘤,强度调制质子治疗(IMPT)具有挑战性。通常对于质子患者选择使用 5 毫米肿瘤运动的上限。在这项研究中,我们提出了(1)一种用于运动大于 5 毫米的肺部肿瘤的稳健且易于实施的治疗计划策略,以及(2)一种用于评估呼吸相上剂量分布的四维计算机断层扫描(4DCT)稳健评估策略。

材料和方法

我们基于内部靶区(ITV)概念创建了一种治疗计划策略(目的 1)。ITV 是在八个 4DCT 相位的临床靶区(CTV)上创建的联合体。在平均 CT(avgCT)上进行稳健优化时,将 ITV 扩展 2 毫米作为目标。临床计划可接受性基于稳健评估来判断,计算平均 CT 上 28 个误差场景(范围和设置误差)中的体素最小和最大(VWmin/max)剂量。该计划是在 RayStation(瑞典斯德哥尔摩的 RaySearch Laboratories)中使用蒙特卡罗剂量引擎创建的,该引擎经过委托,用于我们的 Mevion S250i Hyperscan 系统(美国马萨诸塞州利特尔顿的 Mevion Medical Systems)。我们开发了一种新的 4D 稳健评估方法(4DRobAvg;目的 2)。在每个单独的 4DCT 相位上计算了 28 个场景剂量。对于每个场景,将各个相位上的剂量分布变形到参考相位并组合成加权和,从而得到 28 个加权和场景剂量分布。从这些 28 个场景剂量中,计算 VWmin/max 剂量。将这种新的 4D 稳健评估与两种更简单的 4D 评估策略进行了比较:在每个单独的 4DCT 相位上重新计算标称计划(4DNom)和在每个单独的相位上计算稳健 VWmin/max 剂量(4DRobInd)。为 16 名肿瘤运动为 4-26 毫米的肺癌患者评估了治疗计划和剂量评估策略。

结果

随着肿瘤幅度的增加,ITV 和 CTV 体积的比值呈线性增加,平均比值为 1.4。尽管 ITV 体积较大,但对于所有患者,仍可实现满足所有靶区和危及器官(OAR)限制的临床可接受计划。发现 4DNom 和 4DRobInd 评估策略分别低估或高估了肿瘤运动的剂量学效应。4DRobInd 显示五个患者的靶区剂量不足,这在 avgCT 上的稳健评估或 4DRobAvg 中均未观察到。使用 4DRobAvg 的剂量变形的准确性进行了量化,并发现可以接受,在大多数情况下,剂量体积参数的差异小于 1Gy。

结论

所提出的基于 ITV 的平均 CT 上的计划策略被发现是一种具有临床可行性的方法,具有足够的肿瘤覆盖范围,并且即使对于较大的肿瘤运动也不会对 OAR 造成过度剂量。新提出的 4D 稳健评估,4DRobAvg,被证明可以很好地理解呼吸运动剂量分布的影响,并准确估计在不同呼吸相上输送的剂量。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/5821/8456954/ce9c5ab2f5af/MP-48-4425-g001.jpg
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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/5821/8456954/ce9c5ab2f5af/MP-48-4425-g001.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/5821/8456954/c74df8dba5de/MP-48-4425-g005.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/5821/8456954/fcc025395c28/MP-48-4425-g002.jpg
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