人体尺度 X 射线暗场成像的真实波光学模拟

Yongjin Sung, Brandon Nelson, Rajiv Gupta
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摘要

背景:X 射线暗场成像(XDFI)被认为在诊断许多病理情况时比传统 X 射线成像具有更高的性能。然而,目前还没有一种模拟工具能可靠地预测人体尺度的临床 XDFI 图像。目的:据我们所知,本文首次展示了人体尺度的 XDFI 仿真。利用开发的模拟工具,我们展示了 XDFI 在诊断肺气肿、肺纤维化、肺水肿和肺炎方面的优势和局限性。方法:我们用 Voronoi 网格增强 XCAT 模体以模拟肺泡次结构(负责肺部暗视野信号),为每种组织类型分配材料属性,并使用多层波光学传播模拟 X 射线波在增强 XCAT 模体中的传播。通过改变 Voronoi 网格的密度和厚度以及材料属性,我们模拟了正常和患病肺部的 XDFI 图像。结果:我们的模拟框架可以生成人体胸部正常或患病肺部的逼真 XDFI 图像。模拟证实,正常肺、气肿肺和纤维化肺显示出明显不同的暗场信号。模拟还显示,肺炎时肺泡积液、间质水肿时肺壁增厚以及肺大泡时的放气会导致暗场信号的类似减弱。结论:利用肺部亚结构增强 XCAT 并使用多层波光学技术生成逼真的 XDFI 图像是可行的。通过提供最逼真的肺部病理 XDFI 图像,所开发的模拟框架将有助于进行室内临床试验以及 XDFI 硬件和软件的优化。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Realistic wave-optics simulation of X-ray dark-field imaging at a human scale
Background: X-ray dark-field imaging (XDFI) has been explored to provide superior performance over the conventional X-ray imaging for the diagnosis of many pathologic conditions. A simulation tool to reliably predict clinical XDFI images at a human scale, however, is currently missing. Purpose: In this paper, we demonstrate XDFI simulation at a human scale for the first time to the best of our knowledge. Using the developed simulation tool, we demonstrate the strengths and limitations of XDFI for the diagnosis of emphysema, fibrosis, atelectasis, edema, and pneumonia. Methods: We augment the XCAT phantom with Voronoi grids to simulate alveolar substructure, responsible for the dark-field signal from lungs, assign material properties to each tissue type, and simulate X-ray wave propagation through the augmented XCAT phantom using a multi-layer wave-optics propagation. Altering the density and thickness of the Voronoi grids as well as the material properties, we simulate XDFI images of normal and diseased lungs. Results: Our simulation framework can generate realistic XDFI images of a human chest with normal or diseased lungs. The simulation confirms that the normal, emphysematous, and fibrotic lungs show clearly distinct dark-field signals. It also shows that alveolar fluid accumulation in pneumonia, wall thickening in interstitial edema, and deflation in atelectasis result in a similar reduction in dark-field signal. Conclusions: It is feasible to augment XCAT with pulmonary substructure and generate realistic XDFI images using multi-layer wave optics. By providing the most realistic XDFI images of lung pathologies, the developed simulation framework will enable in-silico clinical trials and the optimization of both hardware and software for XDFI.
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