MicroComputed Tomography

Springer Handbook of Microscopy Pub Date : 2018-10-03 DOI:10.1201/9781420058772

A. Lin, S. Stock, R. Guldberg

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引用次数: 32

Abstract

Since Röntgen discovered x-rays at the end of the nineteenth century and established their usefulness for medical diagnostics imaging, many technological advances have allowed for x-rays to be employed in even more powerful ways. This includes utilizing x-rays for tomographic imaging and quantification. This chapter describes the principles of microcomputed tomography (microCT) and its use in obtaining internal structural and compositional data about materials/objects of interest. The authors introduce this material with a brief history of the development of laboratory and synchrotron microCT for engineering, biology, and biomedical applications. As will be evident, microCT imaging requires many components to operate together with precision, and the standard microCT subsystems will be described. This chapter will also explain the principles behind x-ray attenuation in materials as well as common methods by which microCT image processing software may handle complex detected data to reconstruct grayscale slice images. The quality of the resulting images relies on a few key factors, including spatial resolution, noise, and contrast, and these concepts will be explained. Additionally,microCT image reconstruction and processing may produce various types of artifacts, and the most common of these artifacts will be discussed. In a typical microCT imaging workflow, the reconstructed two-dimensional (2-D) slice images can subsequently be processed to generate segmentations and three-dimensional (3-D) renderings of thematerial(s) of interest. Because image segmentation and quantification of the material’s geometry and composition could be performed via many possible procedures, these processes will be generally discussed within this chapter. Finally, microCT forms the basis for various novel techniques that are rapidly gaining momentum for use in biology, engineering, and biomedical research applications to provide accurate, non-destructive high-resolution images and quantitative data. Some of these techniques, such as phase contrast CT, dual-energy CT, fluorescence CT, and x-ray scattering tomography, will be introduced and briefly discussed.

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自从Röntgen在19世纪末发现x射线并确立其在医学诊断成像方面的用途以来，许多技术进步使x射线得以以更强大的方式使用。这包括利用x射线进行层析成像和定量。本章描述了微计算机断层扫描(microCT)的原理及其在获取感兴趣的材料/物体的内部结构和成分数据方面的应用。作者介绍了这种材料与实验室和同步加速器微ct的发展简史工程，生物学和生物医学应用。很明显，微ct成像需要许多组件一起精确操作，标准微ct子系统将被描述。本章还将解释材料中x射线衰减的原理，以及microCT图像处理软件处理复杂检测数据以重建灰度切片图像的常用方法。所产生的图像的质量依赖于几个关键因素，包括空间分辨率，噪声和对比度，这些概念将被解释。此外，微ct图像重建和处理可能产生各种类型的伪影，这些伪影中最常见的将被讨论。在典型的微ct成像工作流程中，重建的二维(2-D)切片图像随后可以被处理以生成感兴趣材料的分割和三维(3-D)渲染。由于图像分割和量化材料的几何形状和组成可以通过许多可能的程序来执行，这些过程将在本章中进行一般讨论。最后，微ct形成了各种新技术的基础，这些技术在生物学、工程和生物医学研究应用中迅速获得动力，提供准确、无损的高分辨率图像和定量数据。其中一些技术，如相衬CT、双能CT、荧光CT和x射线散射断层扫描，将被介绍和简要讨论。

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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Springer Handbook of Microscopy

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