基于三维点云检测和堆叠集合学习的肺癌 SBRT 肿瘤运动监测可行性研究。

IF 1.3 Q3 RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING

Journal of Medical Imaging and Radiation Sciences Pub Date : 2024-08-10 DOI:10.1016/j.jmir.2024.101729

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引用次数: 0

摘要

目的：从可行性角度构建肺癌立体定向体放射治疗（SBRT）的肿瘤运动监测模型：方法：收集了 22 名患者的 32 个治疗计划，以计划 CT 和计划靶体积（PTV）的中心点位置为参考。采集不同呼吸阶段的 4DCT 图像，重新定义目标并获得浮动 PTV 中心点位置。根据规划的 CT 和 CBCT 注册参数，完成了数据扩增，获得了 2130 个实验记录用于分析。我们采用堆叠多学习集合方法拟合体表三维点云变化和目标位置变化，构建肿瘤运动监测模型，并用均方根误差（RMSE）和R-Square（R2）评估预测精度：结果：堆叠集合模型的预测位移在各个方向上都与参考值高度一致。在第一层模型中，X 方向（RMSE =0.019 ∼ 0.145mm，R2 =0.9793∼0.9996）和 Z 方向（RMSE = 0.051 ∼ 0.168 mm, R2 = 0.9736∼0.9976) 显示出最好的结果，而 Y 方向则排名靠后（RMSE = 0.088 ∼ 0.224 mm, R2 = 0.9553∼ 0.9933）。第二层模型总结了第一层单元模型的优点，X、Y、Z 的 RMSE 分别为 0.015 mm、0.083 mm、0.041 mm，R2 分别为 0.9998、0.9931、0.9984：肺癌 SBRT 的肿瘤运动监测方法具有非电离、无创、无标记、实时等潜在应用价值。

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A feasibility study of tumor motion monitoring for SBRT of lung cancer based on 3D point cloud detection and stacking ensemble learning

Purpose

To construct a tumor motion monitoring model for stereotactic body radiation therapy (SBRT) of lung cancer from a feasibility perspective.

Methods

A total of 32 treatment plans for 22 patients were collected, whose planning CT and the centroid position of the planning target volume (PTV) were used as the reference. Images of different respiratory phases in 4DCT were acquired to redefine the targets and obtain the floating PTV centroid positions. In accordance with the planning CT and CBCT registration parameters, data augmentation was accomplished, yielding 2130 experimental recordings for analysis. We employed a stacking multi-learning ensemble approach to fit the 3D point cloud variations of body surface and the change of target position to construct the tumor motion monitoring model, and the prediction accuracy was assess using root mean squared error (RMSE) and R-Square (R²).

Results

The prediction displacement of the stacking ensemble model shows a high degree of agreement with the reference value in each direction. In the first layer of model, the X direction (RMSE =0.019 ∼ 0.145mm, R² =0.9793∼0.9996) and the Z direction (RMSE = 0.051 ∼ 0.168 mm, R² = 0.9736∼0.9976) show the best results, while the Y direction ranked behind (RMSE = 0.088 ∼ 0.224 mm, R² = 0.9553∼ 0.9933). The second layer model summarizes the advantages of unit models of first layer, and RMSE of 0.015 mm, 0.083 mm, 0.041 mm, and R² of 0.9998, 0.9931, 0.9984 respectively for X, Y, Z were obtained.

Conclusions

The tumor motion monitoring method for SBRT of lung cancer has potential application of non-ionization, non-invasive, markerless, and real-time.

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来源期刊

Journal of Medical Imaging and Radiation Sciences RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING-

CiteScore

2.30

自引率

11.10%

发文量

231

审稿时长

53 days

期刊介绍： Journal of Medical Imaging and Radiation Sciences is the official peer-reviewed journal of the Canadian Association of Medical Radiation Technologists. This journal is published four times a year and is circulated to approximately 11,000 medical radiation technologists, libraries and radiology departments throughout Canada, the United States and overseas. The Journal publishes articles on recent research, new technology and techniques, professional practices, technologists viewpoints as well as relevant book reviews.