Department of Environmental Sciences, The University of Toledo , Toledo, Ohio 43606, United States.
Franz Theodore Stone Laboratory, The Ohio State University , Put-in-Bay, Ohio 43456, United States.
Environ Sci Technol. 2015 Dec 15;49(24):14221-9. doi: 10.1021/acs.est.5b03029. Epub 2015 Nov 13.
We discuss the uncertainty associated with a commonly used method for measuring the concentration of microcystin, a group of toxins associated with cyanobacterial blooms. Such uncertainty is rarely reported and accounted for in important drinking water management decisions. Using monitoring data from Ohio Environmental Protection Agency and from City of Toledo, we document the sources of measurement uncertainty and recommend a Bayesian hierarchical modeling approach for reducing the measurement uncertainty. Our analysis suggests that (1) much of the uncertainty is a result of the highly uncertain "standard curve" developed during each test and (2) the uncertainty can be reduced by pooling raw test data from multiple tests. Based on these results, we suggest that estimation uncertainty can be effectively reduced through the effort of either (1) regional regulatory agencies by sharing and combining raw test data from regularly scheduled microcystin monitoring program or (2) the manufacturer of the testing kit by conducting additional tests as part of an effort to improve the testing kit.
我们讨论了一种常用的微囊藻毒素浓度测量方法所涉及的不确定性,微囊藻毒素是与蓝藻水华有关的一组毒素。这种不确定性很少在重要的饮用水管理决策中报告和考虑。我们使用俄亥俄州环境保护局和托莱多市的监测数据,记录了测量不确定性的来源,并推荐了一种贝叶斯层次建模方法来降低测量不确定性。我们的分析表明,(1)很大一部分不确定性是由于每次测试中高度不确定的“标准曲线”造成的,(2)通过合并来自多个测试的原始测试数据,可以降低不确定性。基于这些结果,我们建议可以通过以下两种方式有效地降低估计不确定性:(1)区域监管机构通过共享和组合定期微囊藻毒素监测计划的原始测试数据,或(2)测试试剂盒的制造商通过进行额外的测试来改进测试试剂盒。
