氡潜能、地质构造与肺癌风险。

Radon potential, geologic formations, and lung cancer risk.

作者信息

Hahn Ellen J, Gokun Yevgeniya, Andrews William M, Overfield Bethany L, Robertson Heather, Wiggins Amanda, Rayens Mary Kay

机构信息

Clean Indoor Air Partnership, College of Nursing, University of Kentucky, United States.

Kentucky Geological Survey, University of Kentucky, United States.

出版信息

Prev Med Rep. 2015 May 2;2:342-6. doi: 10.1016/j.pmedr.2015.04.009. eCollection 2015.

DOI:10.1016/j.pmedr.2015.04.009

PMID:26844090

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4721325/

Abstract

OBJECTIVE

Exposure to radon is associated with approximately 10% of U.S. lung cancer cases. Geologic rock units have varying concentrations of uranium, producing fluctuating amounts of radon. This exploratory study examined the spatial and statistical associations between radon values and geological formations to illustrate potential population-level lung cancer risk from radon exposure.

METHOD

This was a secondary data analysis of observed radon values collected in 1987 from homes (N = 309) in Kentucky and geologic rock formation data from the Kentucky Geological Survey. Radon value locations were plotted on digital geologic maps using ArcGIS and linked to specific geologic map units. Each map unit represented a package of different types of rock (e.g., limestone and/or shale). Log-transformed radon values and geologic formation categories were compared using one-way analysis of variance.

RESULTS

Observed radon levels varied significantly by geologic formation category. Of the 14 geologic formation categories in north central Kentucky, four were associated with median radon levels, ranging from 8.10 to 2.75 pCi/L.

CONCLUSION

Radon potential maps that account for geologic factors and observed radon values may be superior to using observed radon values only. Knowing radon-prone areas could help target population-based lung cancer prevention interventions given the inequities that exist related to radon.

摘要

目的

在美国，约10%的肺癌病例与氡暴露有关。地质岩石单元中铀的浓度各不相同，会产生数量波动的氡。这项探索性研究考察了氡值与地质构造之间的空间和统计关联，以阐明氡暴露在人群层面导致肺癌的潜在风险。

方法

这是一项对1987年从肯塔基州家庭（N = 309）收集的实测氡值以及肯塔基州地质调查局的地质岩石构造数据进行的二次数据分析。利用ArcGIS将氡值位置标绘在数字地质图上，并与特定的地质图单元建立联系。每个图单元代表一组不同类型的岩石（如石灰岩和/或页岩）。采用单向方差分析比较经对数转换的氡值和地质构造类别。

结果

实测氡水平因地质构造类别而异。在肯塔基州中北部的14个地质构造类别中，有4个与氡水平中位数相关，范围在8.10至2.75皮居里/升之间。

结论

考虑地质因素和实测氡值的氡潜能图可能优于仅使用实测氡值的图。鉴于氡暴露存在的不平等现象，了解氡易发地区有助于确定以人群为基础的肺癌预防干预目标。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/45d8/4721325/61959c93b186/gr1.jpg

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氡潜能、地质构造与肺癌风险。

Radon potential, geologic formations, and lung cancer risk.

作者信息

机构信息

出版信息

OBJECTIVE

METHOD

RESULTS

CONCLUSION

目的

方法

结果

结论

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