Automated Linac QA Using Scripting and Varian Developer Mode

International Journal of Medical Physics, Clinical Engineering and Radiation Oncology Pub Date : 2021-01-01 DOI:10.4236/ijmpcero.2021.104013

K. Pearman, Nicholas Koch, D. Wiant, Han Liu, B. Sintay

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Abstract

Purpose: Linac quality assurance (QA) can be time consuming involving set up, execution, analysis and subject to user variability. The purpose of this study is to develop qualitative automation tools for mechanical and imaging QA to improve efficiency, consistency, and accuracy. Methods and Materials: Traditionally QA has been performed with graph paper, film, and multiple phantoms. Analysis consists of ruler and vendor provided software. We have developed a single four-phantom method for QA procedures including light-radiation coincidence, imaging quality, table motion and Isocentricity and separately cone beam computed tomography. XML scripts were developed to execute a series of tasks using Varian’s Truebeam Developer Mode. Non-phantom QA procedures have also been developed including field size, dose rate, MLC position, MLC and gantry speed, star shot, Winston-Lutz and Half Beam Block. All analysis is performed using inhouse MATLAB codes. Results: Overall time savings were 2.2 hours per Linac per month. Consistency improvements (standard deviation, STD) were observed for some tests. For example: field size improved from 0.11 mm to 0.04 mm and table motion improved from 0.17 mm to 0.12 mm. CBCT STD improved from 0.99 mm to 0.61 mm for slice thickness. No STD change was observed for Isocentricity test. We noticed an increase in STD from 0.33 mm to 0.41 mm for light-radiation coincidence test. There was a small drop in field size accuracy. Isocentricity showed an increase in measurement accuracy from 0.47 mm to 0.15 mm. Table motion increased in accuracy from 0.20 mm to 0.16 mm. Conclusion: Automation is a viable, accurate and efficient option for monthly and annual QA.

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使用脚本和瓦里安开发模式自动直线测试

目的:Linac质量保证(QA)可能涉及设置，执行，分析和受用户变化的影响。本研究的目的是开发用于机械和成像质量保证的定性自动化工具，以提高效率、一致性和准确性。方法和材料:传统的QA是用方格纸、胶片和多个模型来进行的。分析由标尺和供应商提供的软件组成。我们已经开发了一种单一的四幻影方法，用于QA程序，包括光辐射一致性，成像质量，工作台运动和等心性，以及单独的锥束计算机断层扫描。开发XML脚本，使用瓦里安的Truebeam开发者模式执行一系列任务。非幻影质量保证程序也已开发，包括场大小，剂量率，MLC位置，MLC和龙门架速度，星射，温斯顿-卢茨和半光束块。所有的分析都是使用内部的MATLAB代码执行的。结果:每个Linac每月节省的总时间为2.2小时。在一些测试中观察到一致性改善(标准偏差，STD)。例如:场地尺寸从0.11毫米提高到0.04毫米，工作台运动从0.17毫米提高到0.12毫米。CBCT STD层厚度由0.99 mm提高到0.61 mm。等向心性试验未见性病改变。我们注意到光辐射一致性测试的STD从0.33 mm增加到0.41 mm。在场尺寸精度上有一个小的下降。等心度测量精度由0.47 mm提高到0.15 mm。工作台运动精度从0.20毫米增加到0.16毫米。结论:自动化是月度和年度质量保证的可行、准确和高效的选择。

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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International Journal of Medical Physics, Clinical Engineering and Radiation Oncology

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