用于生物医学研究的实验室 X 射线纳米计算机断层扫描技术

Till DreierLund University Department of Medical Radiation PhysicsExcillum AB, Robin KrügerLund University Department of Medical Radiation Physics, Gustaf BernströmLund University Department of Experimental Medical Science, Karin Tran-LundmarkLund University Department of Experimental Medical ScienceLund University Wallenberg Center for Molecular MedicineThe Pediatric Heart Center, Skåne University Hospital, Isabel GonçalvesCardiology, Skåne University Hospital, Martin BechLund University Department of Medical Radiation Physics
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引用次数: 0

摘要

高分辨率 X 射线断层扫描是利用同步辐射源进行生物医学研究的常用技术。随着实验室 X 射线源的发展,越来越多的实验可以在实验室中进行。本文介绍了一种用于 X 射线纳米计算机断层扫描的实验室装置的设计、实施和验证,该装置使用纳米聚焦 X 射线源和高几何放大率,不需要任何光学元件。将基于闪烁体的探测器与光子计数探测器进行比较后发现,在 X 射线源流量有限且样品对比度较低的情况下,使用光子计数探测器在这些应用中具有明显的优势。利用基于传播的相位对比增强了样品对比度。使用二维分辨率图表和重建 CT 切片上的傅立叶环形相关性来验证系统的分辨率。对噪声和对比度的评估凸显了光子计数探测器和相位对比度提高对比度的优势。所实现的装置能够达到亚微米级分辨率,并能满足生物样本(如石蜡包埋组织)的对比度要求。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Laboratory x-ray nano-computed tomography for biomedical research
High-resolution x-ray tomography is a common technique for biomedical research using synchrotron sources. With advancements in laboratory x-ray sources, an increasing number of experiments can be performed in the lab. In this paper, the design, implementation, and verification of a laboratory setup for x-ray nano-computed tomography is presented using a nano-focus x-ray source and high geometric magnification not requiring any optical elements. Comparing a scintillator-based detector to a photon counting detector shows a clear benefit of using photon counting detectors for these applications, where the flux of the x-ray source is limited and samples have low contrast. Sample contrast is enhanced using propagation-based phase contrast. The resolution of the system is verified using 2D resolution charts and using Fourier Ring Correlation on reconstructed CT slices. Evaluating noise and contrast highlights the benefits of photon counting detectors and the contrast improvement through phase contrast. The implemented setup is capable of reaching sub-micron resolution and satisfying contrast in biological samples, like paraffin embedded tissue.
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