Computational Tool for Calculation of Tissue Air Ratio and Tissue Maximum Ratio in Radiation Dosimetry

Current Trends in Biomedical Engineering & Biosciences Pub Date : 2019-01-03 DOI:10.19080/ctbeb.2019.17.555966

Atia Atiq

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引用次数: 2

Abstract

In radiation therapy, it is essential to calculate the dosimetric quantities such as Percentage Depth Dose (PDD), Tissue Air Ratio (TAR), and Tissue Maximum Ratio (TMR). The basic depth dose data was determined by dosimetric measurements taken in dummy patients (phantoms), which have density nearly equal to human body tissues, with ionization chamber placed in them [1]. A system for absorbed dose calculations has been developed to foresee the depth dose distribution in patients going to be treated. The radiation dose deposited by ionizing radiations within the patient or medium varies with the varying depth. This variation is due to different parameters like depth, beam energy, field size, Source to Surface Distance (SSD). While calculating absorbed doses, greater considerations must be given to these parameters as they cause changes to depth dose distributions [2]. Plenty of radiotherapy units, such as linac and cobalt-60 units, accomplish the treatment of cancerous parts. To treat cancerous tissues, cobalt 60 gamma ray beam is used for more than fifty years in radiotherapy [3].

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辐射剂量学中组织空气比和组织最大比的计算工具

在放射治疗中，必须计算剂量学量，如百分比深度剂量(PDD)、组织空气比(TAR)和组织最大比(TMR)。基本的深度剂量数据是通过在假病人(幻影)中进行的剂量学测量来确定的，假病人的密度几乎等于人体组织，并在其中放置电离室。一种计算吸收剂量的系统已被开发出来，以预测将要治疗的病人体内的深度剂量分布。电离辐射在病人或介质内沉积的辐射剂量随深度的变化而变化。这种变化是由于不同的参数，如深度，光束能量，场大小，源到表面距离(SSD)。在计算吸收剂量时，必须更多地考虑这些参数，因为它们会引起深度剂量分布的变化。许多放射治疗装置，如直线加速器和钴-60装置，可以完成癌变部位的治疗。为了治疗癌变组织，钴60伽马射线束在放射治疗中使用了50多年。

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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Current Trends in Biomedical Engineering & Biosciences

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