Department of Radiation Oncology and Image-Applied Therapy, Kyoto University Graduate School of Medicine, Kyoto 606-8507, Japan.
Med Phys. 2009 Oct;36(10):4328-39. doi: 10.1118/1.3213083.
The aim of this study was to develop a 4D-modeling algorithm, designated "3D+," to simulate organ movement and deformation for 4D dose calculation without the need for 4D-CT or deformable image registration and to assess the validity of this algorithm.
This 3D+ algorithm virtually creates 4D-CT images by deforming static 3D-CT data according to a typical motion model and motion data at multiple observation points collected via fluoroscopy. A typical motion model intended for patients with lung tumors immobilized with a vacuum pillow inside a stereotactic body frame was constructed. The geometric accuracy of virtual 4D-CT images created using this 3D+ algorithm was evaluated in eight patients by comparing the simulated results with actual 4D-CT images in terms of visual assessment, landmark analysis, and comparison of the radial distance from the tumor centroid to the body or lung surface.
The average accuracy for all patients, as determined via landmark analysis, was 2.8 +/- 1.8 mm, very similar to results obtained through 4D-CT and deformable image registrations. Error in the radial distance from the tumor centroid to the body or lung surface was generally within 1.0 or 2.0 mm, respectively, in virtual versus actual 4D-CT images. Therefore, it is assumed that these geometric errors would have only negligible effects on dose calculation.
4D modeling of the thorax utilizing the 3D+ algorithm shows acceptable accuracy and is more suited for routine clinical use in terms of processing time than conventional 4D-CT and deformable image registration. The 3D+ algorithm may be useful for simulating dose distribution for advanced beam delivery techniques, such as real-time tumor tracking irradiation and adaptive radiation therapy.
本研究旨在开发一种名为“3D+”的 4D 建模算法,用于模拟器官运动和变形,以便在无需 4D-CT 或变形图像配准的情况下进行 4D 剂量计算,并评估该算法的有效性。
该 3D+算法通过根据典型运动模型和通过透视采集的多个观察点的运动数据对静态 3D-CT 数据进行变形,从而虚拟地创建 4D-CT 图像。构建了用于在立体定向体架内使用真空枕固定的肺部肿瘤患者的典型运动模型。通过在 8 名患者中比较模拟结果与实际 4D-CT 图像,从视觉评估、标志点分析以及肿瘤中心点到体表或肺表面的径向距离比较三个方面评估了使用该 3D+算法创建的虚拟 4D-CT 图像的几何精度。
通过标志点分析确定的所有患者的平均精度为 2.8 ± 1.8mm,与 4D-CT 和变形图像配准的结果非常相似。肿瘤中心点到体表或肺表面的径向距离误差在虚拟与实际 4D-CT 图像中通常分别在 1.0 或 2.0mm 以内。因此,假设这些几何误差对剂量计算的影响可以忽略不计。
利用 3D+算法对胸部进行 4D 建模显示出可接受的精度,并且在处理时间方面比传统的 4D-CT 和变形图像配准更适合常规临床应用。3D+算法可用于模拟先进射束输送技术(如实时肿瘤跟踪照射和自适应放疗)的剂量分布。
