Zhang Lian, Holmes Jason M, Liu Zhengliang, Vora Sujay A, Sio Terence T, Vargas Carlos E, Yu Nathan Y, Keole Sameer R, Schild Steven E, Bues Martin, Li Sheng, Liu Tianming, Shen Jiajian, Wong William W, Liu Wei
Department of Radiation Oncology, Mayo Clinic, Phoenix, Arizona, USA.
School of Computing, University of Georgia, Athens, Georgia, USA.
Med Phys. 2024 Feb;51(2):1484-1498. doi: 10.1002/mp.16758. Epub 2023 Sep 25.
Accurate and efficient dose calculation is essential for on-line adaptive planning in proton therapy. Deep learning (DL) has shown promising dose prediction results in photon therapy. However, there is a scarcity of DL-based dose prediction methods specifically designed for proton therapy. Successful dose prediction method for proton therapy should account for more challenging dose prediction problems in pencil beam scanning proton therapy (PBSPT) due to its sensitivity to heterogeneities.
To develop a DL-based PBSPT dose prediction workflow with high accuracy and balanced complexity to support on-line adaptive proton therapy clinical decision and subsequent replanning.
PBSPT plans of 103 prostate cancer patients (93 for training and the other 10 for independent testing) and 83 lung cancer patients (73 for training and the other 10 for independent testing) previously treated at our institution were included in the study, each with computed tomography scans (CTs), structure sets, and plan doses calculated by the in-house developed Monte-Carlo dose engine (considered as the ground truth in the model training and testing). For the ablation study, we designed three experiments corresponding to the following three methods: (1) Experiment 1, the conventional region of interest (ROI) (composed of targets and organs-at-risk [OARs]) method. (2) Experiment 2, the beam mask (generated by raytracing of proton beams) method to improve proton dose prediction. (3) Experiment 3, the sliding window method for the model to focus on local details to further improve proton dose prediction. A fully connected 3D-Unet was adopted as the backbone. Dose volume histogram (DVH) indices, 3D Gamma passing rates with a criterion of 3%/3 mm/10%, and dice coefficients for the structures enclosed by the iso-dose lines between the predicted and the ground truth doses were used as the evaluation metrics. The calculation time for each proton dose prediction was recorded to evaluate the method's efficiency.
Compared to the conventional ROI method, the beam mask method improved the agreement of DVH indices for both targets and OARs and the sliding window method further improved the agreement of the DVH indices (for lung cancer, CTV D98 absolute deviation: 0.74 ± 0.18 vs. 0.57 ± 0.21 vs. 0.54 ± 0.15 Gy[RBE], ROI vs. beam mask vs. sliding window methods, respectively). For the 3D Gamma passing rates in the target, OARs, and BODY (outside target and OARs), the beam mask method improved the passing rates in these regions and the sliding window method further improved them (for prostate cancer, targets: 96.93% ± 0.53% vs. 98.88% ± 0.49% vs. 99.97% ± 0.07%, BODY: 86.88% ± 0.74% vs. 93.21% ± 0.56% vs. 95.17% ± 0.59%). A similar trend was also observed for the dice coefficients. This trend was especially remarkable for relatively low prescription isodose lines (for lung cancer, 10% isodose line dice: 0.871 ± 0.027 vs. 0.911 ± 0.023 vs. 0.927 ± 0.017). The dose predictions for all the testing cases were completed within 0.25 s.
An accurate and efficient deep learning-augmented proton dose prediction framework has been developed for PBSPT, which can predict accurate dose distributions not only inside but also outside ROI efficiently. The framework can potentially further reduce the initial planning and adaptive replanning workload in PBSPT.
准确且高效的剂量计算对于质子治疗中的在线自适应计划至关重要。深度学习(DL)在光子治疗中已显示出有前景的剂量预测结果。然而,专门为质子治疗设计的基于DL的剂量预测方法却很匮乏。由于铅笔束扫描质子治疗(PBSPT)对不均匀性敏感,成功的质子治疗剂量预测方法应考虑到其中更具挑战性的剂量预测问题。
开发一种基于DL的高精度且复杂度平衡的PBSPT剂量预测工作流程,以支持在线自适应质子治疗的临床决策及后续的重新计划。
本研究纳入了我院之前治疗的103例前列腺癌患者(93例用于训练,另10例用于独立测试)和83例肺癌患者(73例用于训练,另10例用于独立测试)的PBSPT计划,每位患者均有计算机断层扫描(CT)、结构集以及由内部开发的蒙特卡罗剂量引擎计算的计划剂量(在模型训练和测试中视为真实值)。对于消融研究,我们设计了三个实验,分别对应以下三种方法:(1)实验1,传统的感兴趣区域(ROI)(由靶区和危及器官[OARs]组成)方法。(2)实验2,束流掩码(通过质子束的光线追踪生成)方法以改善质子剂量预测。(3)实验3,滑动窗口方法,使模型聚焦于局部细节以进一步改善质子剂量预测。采用全连接3D-Unet作为主干网络。剂量体积直方图(DVH)指标、标准为3%/3mm/10%的3D伽马通过率以及预测剂量与真实剂量之间等剂量线所包围结构的骰子系数用作评估指标。记录每次质子剂量预测的计算时间以评估该方法的效率。
与传统的ROI方法相比,束流掩码方法提高了靶区和OARs的DVH指标一致性,滑动窗口方法进一步提高了DVH指标的一致性(对于肺癌,临床靶区(CTV)D98绝对偏差:分别为0.74±0.18 Gy[RBE]、0.57±0.21 Gy[RBE]、0.54±0.15 Gy[RBE],ROI方法、束流掩码方法、滑动窗口方法)。对于靶区、OARs和体部(靶区和OARs之外)的3D伽马通过率,束流掩码方法提高了这些区域的通过率,滑动窗口方法进一步提高了通过率(对于前列腺癌,靶区:96.93%±0.53%、98.88%±0.49%、99.97%±0.07%,体部:86.88%±0.74%、93.21%±0.56%、95.17%±0.59%)。骰子系数也观察到类似趋势。这种趋势在相对较低的处方等剂量线时尤为显著(对于肺癌,10%等剂量线骰子系数:0.871±0.027、0.911±0.023、0.927±0.017)。所有测试病例的剂量预测均在0.25秒内完成。
已为PBSPT开发了一个准确且高效的深度学习增强质子剂量预测框架,该框架不仅能高效预测ROI内部的准确剂量分布,还能预测其外部的剂量分布。该框架有可能进一步减少PBSPT中的初始计划和自适应重新计划工作量。
