Data-Driven Volumetric CT Image Generation from Surface Structures using a Patient-Specific Deep Leaning Model.

IF 6.4 1区医学 Q1 ONCOLOGY

International Journal of Radiation Oncology Biology Physics Pub Date : 2024-11-20 DOI:10.1016/j.ijrobp.2024.11.077

Shaoyan Pan, Chih-Wei Chang, Zhen Tian, Tonghe Wang, Marian Axente, Joseph Shelton, Tian Liu, Justin Roper, Xiaofeng Yang

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引用次数: 0

Abstract

Purpose: Optical surface imaging presents radiation-dose-free and noninvasive approaches for image-guided radiotherapy, allowing continuous monitoring during treatment delivery. However, it falls short in cases where correlation of motion between body surface and internal tumor is complex, limiting the use of purely surface-guided surrogates for tumor tracking. Relying solely on surface-guided radiation therapy (SGRT) may not ensure accurate intra-fractional monitoring. This work aims to develop a data-driven framework, mitigating the limitations of SGRT in lung cancer radiotherapy by reconstructing volumetric CT images from surface images.

Methods and materials: We conducted a retrospective analysis involving 50 lung cancer patients who underwent radiotherapy and had 10-phase 4DCT scans during their treatment simulation. For each patient, we utilized nine phases of 4DCT images for patient-specific model training and validation, reserving one phase for testing purposes. Our approach employed a surface-to-volume image synthesis framework, harnessing cycle-consistency generative adversarial networks to transform surface images into volumetric representations. The framework was extensively validated using an additional 6-patient cohort with re-simulated 4DCT.

Results: The proposed technique has produced accurate volumetric CT images from the patient's body surface. In comparison to the ground truth CT images, those generated synthetically by the proposed method exhibited the GTV center of mass difference of 1.72±0.87 mm, the overall mean absolute error of 36.2±7.0 HU, structural similarity index measure of 0.94±0.02, and Dice score coefficient of 0.81±0.07. Furthermore, the robustness of the proposed framework was found to be linked to respiratory motion.

Conclusion: The proposed approach provides a novel solution to overcome the limitation of SGRT for lung cancer radiotherapy, which can potentially enable real-time volumetric imaging during radiation treatment delivery for accurate tumor tracking without radiation-induced risk. This data-driven framework offers a comprehensive solution to tackle motion management in radiotherapy, without necessitating the rigid application of first principles modeling for organ motion.

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利用特定患者的深度倾斜模型，从表面结构生成数据驱动的容积 CT 图像。

目的：光学表面成像为图像引导放疗提供了无辐射剂量和无创的方法，可在治疗过程中进行连续监测。然而，在体表和内部肿瘤之间的运动相关性复杂的情况下，光学表面成像就显得力不从心，从而限制了纯粹的表面引导肿瘤跟踪替代物的使用。仅仅依靠体表引导放射治疗（SGRT）可能无法确保精确的分段内监测。这项工作旨在开发一种数据驱动框架，通过从表面图像重建容积 CT 图像来减轻 SGRT 在肺癌放疗中的局限性：我们对 50 名接受放疗的肺癌患者进行了回顾性分析，这些患者在治疗模拟期间接受了 10 相 4DCT 扫描。对于每位患者，我们利用九个阶段的 4DCT 图像进行特定患者模型的训练和验证，并保留一个阶段用于测试目的。我们的方法采用了从表面到体积的图像合成框架，利用周期一致性生成对抗网络将表面图像转换为体积表示。该框架通过使用重新模拟的 4DCT 对另外 6 个患者队列进行了广泛验证：结果：所提出的技术能从患者体表生成精确的容积 CT 图像。与地面真实 CT 图像相比，该方法合成的图像的 GTV 质量中心差为 1.72±0.87 mm，总体平均绝对误差为 36.2±7.0HU，结构相似性指数为 0.94±0.02，Dice 评分系数为 0.81±0.07。此外，还发现所提框架的鲁棒性与呼吸运动有关：所提出的方法为克服 SGRT 在肺癌放疗中的局限性提供了一种新的解决方案，它有可能在放疗过程中实现实时容积成像，从而在没有辐射风险的情况下准确追踪肿瘤。这一数据驱动框架为解决放疗中的运动管理问题提供了一个全面的解决方案，而无需僵化地应用器官运动的第一原理建模。

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

International Journal of Radiation Oncology Biology Physics 医学-核医学

CiteScore

11.00

自引率

7.10%

发文量

2538

审稿时长

6.6 weeks

期刊介绍： International Journal of Radiation Oncology • Biology • Physics (IJROBP), known in the field as the Red Journal, publishes original laboratory and clinical investigations related to radiation oncology, radiation biology, medical physics, and both education and health policy as it relates to the field. This journal has a particular interest in original contributions of the following types: prospective clinical trials, outcomes research, and large database interrogation. In addition, it seeks reports of high-impact innovations in single or combined modality treatment, tumor sensitization, normal tissue protection (including both precision avoidance and pharmacologic means), brachytherapy, particle irradiation, and cancer imaging. Technical advances related to dosimetry and conformal radiation treatment planning are of interest, as are basic science studies investigating tumor physiology and the molecular biology underlying cancer and normal tissue radiation response.