Department of Radiation Oncology, University Hospital, LMU Munich, 81377, Munich, Germany.
Department of Medical Physics, Faculty of Physics, Ludwig-Maximilians-Universität München (LMU Munich), 85748, Garching bei München, Germany.
Med Phys. 2021 Aug;48(8):4148-4159. doi: 10.1002/mp.14995. Epub 2021 Jun 29.
The implementation of volumetric in-room imaging for online adaptive radiotherapy makes extensive testing of this image data for treatment planning necessary. Especially for proton beams the higher sensitivity to stopping power properties of the tissue results in more stringent requirements. Current approaches mainly focus on recalculation of the plans on the new image data, lacking experimental verification, and ignoring the impact on the plan re-optimization process. The aim of this study was to use gel and film dosimetry coupled with a three-dimensional (3D) printed head phantom (based on the planning CT of the patient) for 3D range verification of intensity-corrected cone beam computed tomography (CBCT) image data for adaptive proton therapy.
Single field uniform dose pencil beam scanning proton plans were optimized for three different patients on the patients' planning CT (planCT) and the patients' intensity-corrected CBCT (scCBCT) for the same target volume using the same optimization constraints. The CBCTs were corrected on projection level using the planCT as a prior. The dose optimized on planCT and recalculated on scCBCT was compared in terms of proton range differences (80% distal fall-off, recalculation). Moreover, the dose distribution resulting from recalculation of the scCBCT-optimized plan on the planCT and the original planCT dose distribution were compared (simulation). Finally, the two plans of each patient were irradiated on the corresponding patient-specific 3D printed head phantom using gel dosimetry inserts for one patient and film dosimetry for all three patients. Range differences were extracted from the measured dose distributions. The measured and the simulated range differences were corrected for range differences originating from the initial plans and evaluated.
The simulation approach showed high agreement with the standard recalculation approach. The median values of the range differences of these two methods agreed within 0.1 mm and the interquartile ranges (IQRs) within 0.3 mm for all three patients. The range differences of the film measurement were accurately matching with the simulation approach in the film plane. The median values of these range differences deviated less than 0.1 mm and the IQRs less than 0.4 mm. For the full 3D evaluation of the gel range differences, the median value and IQR matched those of the simulation approach within 0.7 and 0.5 mm, respectively. scCBCT- and planCT-based dose distributions were found to have a range agreement better than 3 mm (median and IQR) for all considered scenarios (recalculation, simulation, and measurement).
The results of this initial study indicate that an online adaptive proton workflow based on scatter-corrected CBCT image data for head irradiations is feasible. The novel presented measurement- and simulation-based method was shown to be equivalent to the standard literature recalculation approach. Additionally, it has the capability to catch effects of image differences on the treatment plan optimization. This makes the measurement-based approach particularly interesting for quality assurance of CBCT-based online adaptive proton therapy. The observed uncertainties could be kept within those of the registration and positioning. The proposed validation could also be applied for other alternative in-room images, e.g. for MR-based pseudoCTs.
容积式机房成像在在线自适应放疗中的实施需要对这些图像数据进行广泛的治疗计划测试。对于质子束,组织对阻止能力特性的更高敏感性导致更严格的要求。目前的方法主要集中在新图像数据上的计划重新计算上,缺乏实验验证,并且忽略了对计划重新优化过程的影响。本研究的目的是使用凝胶和胶片剂量学以及三维(3D)打印头模型(基于患者的计划 CT)对强度校正的锥形束 CT(CBCT)图像数据进行自适应质子治疗的 3D 射程验证。
针对三名不同的患者,在患者的计划 CT(planCT)和患者的强度校正的 CBCT(scCBCT)上,使用相同的优化约束条件,为三个不同的患者优化了单场均匀剂量铅笔束扫描质子计划。使用 planCT 作为先验对 CBCT 进行投影级校正。比较了在 planCT 上优化的剂量和在 scCBCT 上重新计算的剂量,以评估质子射程差异(80%的远端下降,重新计算)。此外,还比较了从 scCBCT 优化的计划在 planCT 上的重新计算剂量分布和原始 planCT 剂量分布(模拟)的剂量分布。最后,使用凝胶剂量学插件对一名患者和所有三名患者使用胶片剂量学对每个患者的两个计划进行了相应的患者特异性 3D 打印头模型的照射。从测量的剂量分布中提取射程差异。对源于初始计划的射程差异进行了校正,并对测量和模拟的射程差异进行了评估。
模拟方法与标准重新计算方法高度一致。对于所有三名患者,这两种方法的射程差异中位数值相差在 0.1mm 以内,四分位距(IQR)在 0.3mm 以内。胶片测量的射程差异在胶片平面上与模拟方法准确匹配。这些射程差异的中位数值偏差小于 0.1mm,四分位距小于 0.4mm。对于凝胶射程差异的完整 3D 评估,中位数值和 IQR 在 0.7mm 和 0.5mm 以内,与模拟方法匹配。基于 scCBCT 和 planCT 的剂量分布在所有考虑的场景(重新计算、模拟和测量)中都具有优于 3mm(中位数和 IQR)的射程一致性。
本初步研究的结果表明,基于散射校正 CBCT 图像数据的头部照射的在线自适应质子工作流程是可行的。所提出的新的基于测量和模拟的方法与标准文献重新计算方法相当。此外,它具有捕捉治疗计划优化中图像差异影响的能力。这使得基于测量的方法特别适用于基于 CBCT 的在线自适应质子治疗的质量保证。观察到的不确定性可以保持在注册和定位的不确定性范围内。所提出的验证也可应用于其他替代的室内图像,例如基于磁共振的伪 CT。
