Department of Medical Physics, School of Physics and Technology, Wuhan University, Wuhan, 430072, China.
Cancer Center, Union Hospital, Tongji Medical College, Huazhong University of Science and Technology, Wuhan, 430022, China.
Phys Eng Sci Med. 2024 Sep;47(3):907-917. doi: 10.1007/s13246-024-01414-z. Epub 2024 Apr 22.
We proposed a deep learning approach to classify various error types in daily VMAT treatment of head and neck cancer patients based on EPID dosimetry, which could provide additional information to support clinical decisions for adaptive planning. 146 arcs from 42 head and neck patients were analyzed. Anatomical changes and setup errors were simulated in 17,820 EPID images of 99 arcs obtained from 30 patients using in-house software for model training, validation, and testing. Subsequently, 141 clinical EPID images from 47 arcs belonging to the remaining 12 patients were utilized for clinical testing. The hierarchical convolutional neural network (HCNN) model was trained to classify error types and magnitudes using EPID dose difference maps. Gamma analysis with 3%/2 mm (dose difference/distance to agreement) criteria was also performed. The F1 score, a combination of precision and recall, was utilized to evaluate the performance of the HCNN model and gamma analysis. The adaptive fractioned doses were calculated to verify the HCNN classification results. For error type identification, the overall F1 score of the HCNN model was 0.99 and 0.91 for primary type and subtype identification, respectively. For error magnitude identification, the overall F1 score in the simulation dataset was 0.96 and 0.70 for the HCNN model and gamma analysis, respectively; while the overall F1 score in the clinical dataset was 0.79 and 0.20 for the HCNN model and gamma analysis, respectively. The HCNN model-based EPID dosimetry can identify changes in patient transmission doses and distinguish the treatment error category, which could potentially provide information for head and neck cancer treatment adaption.
我们提出了一种基于 EPID 剂量学的深度学习方法,旨在对头颈癌患者的日常 VMAT 治疗中的各种误差类型进行分类,该方法可为自适应计划提供额外的信息支持临床决策。分析了 42 例头颈部患者的 146 个弧。使用内部软件对头颈部 30 例患者的 99 个弧中的 17820 个 EPID 图像进行了解剖结构变化和设置误差模拟,用于模型训练、验证和测试。随后,使用来自其余 12 例患者的 47 个弧中的 141 个临床 EPID 图像进行临床测试。使用 EPID 剂量差值图对分层卷积神经网络(HCNN)模型进行训练,以分类误差类型和幅度。还使用 3%/2mm(剂量差值/协议剂量距离)标准进行伽马分析。F1 分数(精度和召回率的组合)用于评估 HCNN 模型和伽马分析的性能。计算自适应分次剂量以验证 HCNN 分类结果。对于误差类型识别,HCNN 模型的总体 F1 评分为 0.99,主要类型和子类型识别的 F1 评分为 0.91。对于误差幅度识别,在模拟数据集,HCNN 模型和伽马分析的总体 F1 评分为 0.96 和 0.70;而在临床数据集,HCNN 模型和伽马分析的总体 F1 评分为 0.79 和 0.20。基于 HCNN 的 EPID 剂量学可以识别患者传输剂量的变化,并区分治疗误差类别,这可能为头颈部癌症治疗的适应性提供信息。
