Clara Freijo, Joaquin L. Herraiz, F. Arias-Valcayo, Paula Ibáñez, Gabriela Moreno, A. Villa-Abaunza, José Manuel Udías
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引用次数: 0
摘要
胸部 X 射线(CXR)是全球用于检测心肺病变的第一种工具。由于需要较大的视野,这些采集受到散射光子的影响很大。CXR 中的散射会在图像中引入背景,从而降低图像的对比度。我们开发了三种基于深度学习的模型来估计和纠正 CXR 的散射。我们使用蒙特卡洛(Monte Carlo,MC)射线追踪模型模拟从使用不同配置(取决于是否有双能量采集)的 CT 扫描中获得的人体模型的 CXR。模拟的 CXR 包含探测器中直接 X 射线和散射 X 射线的分离贡献。然后,这些模拟数据集被用作多个 NN 的监督训练参考。使用 MultiResUNet 架构训练了三个 NN 模型(单能量和双能量)。使用 MC 代码对 COVID-19 患者胸部 CT 扫描获得的 CXR 对 NN 模型的性能进行了评估。结果表明,NN 模型能够估算和纠正 CXR 的散射贡献,误差小于 5%,对模拟设置的变化具有鲁棒性,并能改善软组织的对比度。单能量模型在真实 CXR 上进行了测试,对散射校正后的 CXR 进行了稳健的估计。
Robustness of Single- and Dual-Energy Deep-Learning-Based Scatter Correction Models on Simulated and Real Chest X-rays
Chest X-rays (CXRs) represent the first tool globally employed to detect cardiopulmonary pathologies. These acquisitions are highly affected by scattered photons due to the large field of view required. Scatter in CXRs introduces background in the images, which reduces their contrast. We developed three deep-learning-based models to estimate and correct scatter contribution to CXRs. We used a Monte Carlo (MC) ray-tracing model to simulate CXRs from human models obtained from CT scans using different configurations (depending on the availability of dual-energy acquisitions). The simulated CXRs contained the separated contribution of direct and scattered X-rays in the detector. These simulated datasets were then used as the reference for the supervised training of several NNs. Three NN models (single and dual energy) were trained with the MultiResUNet architecture. The performance of the NN models was evaluated on CXRs obtained, with an MC code, from chest CT scans of patients affected by COVID-19. The results show that the NN models were able to estimate and correct the scatter contribution to CXRs with an error of <5%, being robust to variations in the simulation setup and improving contrast in soft tissue. The single-energy model was tested on real CXRs, providing robust estimations of the scatter-corrected CXRs.