Computed Tomography of the Chest: Basic Principles

Dhaka Shishu (Children) Hospital Journal Pub Date : 2021-01-28 DOI:10.3329/dshj.v35i1.51717

P. Sarkar, Md Jahangir Alam

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Abstract

Tomography is a process by which an image layer of the body is produced, while the images of the structures above and below that layer are made invisible by blurring. computed tomography (CT), the most widely used cross-sectional imaging methods used in medicine, forms cross-sectional images by avoiding super-imposition of structures that occurs in conventional chest imaging, with a >10-fold increase in attenuation sensitivity, within a second without need for breath holding. Like X-ray, an imaging contrast is generated as a consequence of differences in attenuation between the adjacent tissues. The higher the attenuation of the X-ray beam, the brighter the tissue on CT images, and vice versa. The only drawback is the potentially harmful radiation that is measured according to the amount of radiation received by the whole body. Simply, the amount of radiation from a chest CT is equivalent to 400 X-rays. Standard CT usually takes the image of the whole lung and compresses thick slices of about 7-10 mm into images and contrast can be given to highlight structures. High resolution (HRCT) has excellent spatial resolution and very useful for assessing the architecture of the lung. It does not involve IV contrast, acquires thin, non-contiguous slices, at 10-15 mm intervals with thin slices of lung tissues at regular intervals. This reduces the radiation dose by up to 90% compared to standard CT. The axial images are most commonly viewed using lung, mediastinal and bone window. The pulmonary window is specially used for the interpretation of lung parenchyma, airways and interstitial tissues but the mediastinal window is for the interpretation of mediastinal structures. CT interpretation needs a structured and logical approach. DS (Child) H J 2019; 35(1) : 63-69

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胸部计算机断层扫描:基本原理

断层扫描是一种生成人体图像层的过程，而该层上下的结构图像通过模糊处理变得不可见。计算机断层扫描(CT)是医学中使用最广泛的横断面成像方法，通过避免传统胸部成像中出现的结构叠加而形成横断面图像，在一秒钟内无需屏气即可将衰减灵敏度提高10倍。像x射线一样，成像对比是由于相邻组织之间的衰减差异而产生的。x射线的衰减越高，CT图像上的组织越亮，反之亦然。唯一的缺点是潜在的有害辐射是根据整个身体接受的辐射量来衡量的。简单地说，胸部CT的辐射量相当于400次x光。标准CT通常取全肺图像，将约7- 10mm的厚片压缩成图像，并进行对比以突出结构。高分辨率(HRCT)具有良好的空间分辨率，对评估肺的结构非常有用。它不需要静脉造影剂，每隔10- 15mm获得薄的、非连续的切片，每隔一定的时间获得肺组织薄切片。与标准CT相比，这可减少高达90%的辐射剂量。轴向图像最常通过肺、纵隔和骨窗观察。肺窗专门用于解释肺实质、气道和间质组织，而纵隔窗则用于解释纵隔结构。CT解释需要结构化和逻辑的方法。DS(儿童)hj 2019;35(1): 63-69

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Dhaka Shishu (Children) Hospital Journal

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