SUMRAY: R and Python Codes for Calculating Cancer Risk Due to Radiation Exposure of a Population

Pub Date : 2023-06-30 DOI:10.14407/jrpr.2022.00213
M. Sasaki, K. Furukawa, Daiki Satoh, K. Shimada, S. Kudo, Shunji Takagi, S. Takahara, M. Kai
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Abstract

Background: Quantitative risk assessments should be accompanied by uncertainty analyses of the risk models employed in the calculations. In this study, we aim to develop a computational code named SUMRAY for use in cancer risk projections from radiation exposure taking into account uncertainties. We also aim to make SUMRAY publicly available as a resource for further improvement of risk projection.Materials and Methods: SUMRAY has two versions of code written in R and Python. The risk models used in SUMRAY for all-solid-cancer mortality and incidence were those published in the Life Span Study of a cohort of the atomic bomb survivors in Hiroshima and Nagasaki. The confidence intervals associated with the evaluated risks were derived by propagating the statistical uncertainties in the risk model parameter estimates by the Monte Carlo method.Results and Discussion: SUMRAY was used to calculate the lifetime or time-integrated attributable risks of cancer under an exposure scenario (baseline rates, dose[s], age[s] at exposure, age at the end of follow-up, sex) specified by the user. The results were compared with those calculated using another well-known web-based tool, Radiation Risk Assessment Tool (Rad- RAT; National Institutes of Health), and showed a reasonable agreement within the estimated confidential interval. Compared with RadRAT, SUMRAY can be used for a wide range of applications, as it allows the risk projection with arbitrarily specified risk models and/or population reference data.Conclusion: The reliabilities of SUMRAY with the present risk-model parameters and their variance-covariance matrices were verified by comparing them with those of the other codes. The SUMRAY code is distributed to the public as an open-source code under the Massachusetts Institute of Technology license.
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计算人群辐射暴露导致癌症风险的R和Python代码
背景:定量风险评估应伴随着计算中所采用的风险模型的不确定性分析。在这项研究中,我们的目标是开发一个名为SUMRAY的计算代码,用于考虑不确定性的辐射暴露的癌症风险预测。我们的目标是公开SUMRAY,作为进一步改进风险预测的资源。材料和方法:SUMRAY有两个版本的代码,分别用R和Python编写。SUMRAY中使用的全固体癌症死亡率和发病率的风险模型是在广岛和长崎一组原子弹幸存者的生命周期研究中发表的模型。通过蒙特卡罗方法传播风险模型参数估计中的统计不确定性,得到与评估风险相关的置信区间。结果和讨论:SUMRAY用于计算使用者指定的暴露情景(基线率、剂量、暴露时年龄、随访结束时年龄、性别)下的终身或时间综合归因癌症风险。将结果与另一种知名的网络工具——辐射风险评估工具(Rad- RAT;在估计的保密区间内显示出合理的一致性。与RadRAT相比,SUMRAY的应用范围更广,因为它允许使用任意指定的风险模型和/或人口参考数据进行风险预测。结论:通过与其他程序的风险模型参数及其方差-协方差矩阵的比较,验证了SUMRAY程序对风险模型参数及其方差-协方差矩阵的可靠性。SUMRAY代码在麻省理工学院许可下作为开源代码向公众发布。
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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