A generalization performance study on the boosting radiotherapy dose calculation engine based on super-resolution

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
Yewei Wang , Yaoying Liu , Yanlin Bai , Qichao Zhou , Shouping Xu , Xueying Pang
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引用次数: 0

Abstract

Purpose

During the radiation treatment planning process, one of the time-consuming procedures is the final high-resolution dose calculation, which obstacles the wide application of the emerging online adaptive radiotherapy techniques (OLART). There is an urgent desire for highly accurate and efficient dose calculation methods. This study aims to develop a dose super resolution-based deep learning model for fast and accurate dose prediction in clinical practice.

Method

A Multi-stage Dose Super-Resolution Network (MDSR Net) architecture with sparse masks module and multi-stage progressive dose distribution restoration method were developed to predict high-resolution dose distribution using low-resolution data. A total of 340 VMAT plans from different disease sites were used, among which 240 randomly selected nasopharyngeal, lung, and cervix cases were used for model training, and the remaining 60 cases from the same sites for model benchmark testing, and additional 40 cases from the unseen site (breast and rectum) was used for model generalizability evaluation. The clinical calculated dose with a grid size of 2 mm was used as baseline dose distribution. The input included the dose distribution with 4 mm grid size and CT images. The model performance was compared with HD U-Net and cubic interpolation methods using Dose-volume histograms (DVH) metrics and global gamma analysis with 1%/1 mm and 10% low dose threshold. The correlation between the prediction error and the dose, dose gradient, and CT values was also evaluated.

Results

The prediction errors of MDSR were 0.06–0.84% of Dmean indices, and the gamma passing rate was 83.1–91.0% on the benchmark testing dataset, and 0.02–1.03% and 71.3–90.3% for the generalization dataset respectively. The model performance was significantly higher than the HD U-Net and interpolation methods (p < 0.05). The mean errors of the MDSR model decreased (monotonously by 0.03–0.004%) with dose and increased (by 0.01–0.73%) with the dose gradient. There was no correlation between prediction errors and the CT values.

Conclusion

The proposed MDSR model achieved good agreement with the baseline high-resolution dose distribution, with small prediction errors for DVH indices and high gamma passing rate for both seen and unseen sites, indicating a robust and generalizable dose prediction model. The model can provide fast and accurate high-resolution dose distribution for clinical dose calculation, particularly for the routine practice of OLART.

基于超分辨率的增强放射治疗剂量计算引擎的通用性能研究。
目的:在放射治疗规划过程中,耗时的程序之一是最终的高分辨率剂量计算,这阻碍了新兴的在线自适应放射治疗技术(OLART)的广泛应用。人们迫切需要高精度、高效率的剂量计算方法。本研究旨在开发一种基于剂量超分辨率的深度学习模型,用于临床实践中快速准确的剂量预测:方法:开发了一种带有稀疏掩模模块的多级剂量超分辨率网络(MDSR Net)架构和多级渐进剂量分布还原方法,利用低分辨率数据预测高分辨率剂量分布。共使用了 340 份来自不同疾病部位的 VMAT 图,其中 240 份随机选取的鼻咽、肺和宫颈病例用于模型训练,其余 60 份来自相同部位的病例用于模型基准测试,另外 40 份来自未见部位(乳腺和直肠)的病例用于模型普适性评估。临床计算剂量的网格大小为 2 毫米,作为基线剂量分布。输入包括网格尺寸为 4 毫米的剂量分布和 CT 图像。利用剂量-体积直方图(DVH)指标和全局伽玛分析(1%/1 毫米和 10%低剂量阈值),将模型性能与 HD U-Net 和立方插值法进行了比较。此外,还评估了预测误差与剂量、剂量梯度和 CT 值之间的相关性:在基准测试数据集上,MDSR的预测误差为Dmean指数的0.06%-0.84%,伽马通过率为83.1%-91.0%;在泛化数据集上,MDSR的预测误差为0.02%-1.03%,伽马通过率为71.3%-90.3%。该模型的性能明显高于 HD U-Net 和插值法(p 结论):所提出的 MDSR 模型与基线高分辨率剂量分布具有良好的一致性,DVH 指数的预测误差小,可见和未可见部位的伽马通过率高,表明该模型是一个稳健且可泛化的剂量预测模型。该模型可为临床剂量计算提供快速、准确的高分辨率剂量分布,尤其适用于 OLART 的常规应用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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