对不同气候条件下湖泊微囊藻毒素检测统计模型的评估

IF 5.5 1区 生物学 Q1 MARINE & FRESHWATER BIOLOGY
Grace M. Wilkinson , Jonathan A. Walter , Ellen A. Albright , Rachel F. King , Eric K. Moody , David A. Ortiz
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引用次数: 0

摘要

如果蓝藻产生微囊藻毒素等蓝藻毒素,藻华就会威胁人类健康。定期监测娱乐水域中的微囊藻毒素浓度,为管理行动提供信息,是保护公众健康的一种手段;但是,监测蓝藻毒素需要大量的资源和时间。识别可能产生微囊藻毒素的水体的统计模型可帮助指导监测工作,但不同湖泊和不同年份的藻华严重程度和蓝藻毒素产量存在差异,因此预测工作具有挑战性。我们评估了一个统计分类模型的能力,该模型是根据一个季节的水质调查建立的,时间重复性较低,但空间覆盖范围很广,可用于预测随后几年是否可能在湖泊中检测到微囊藻毒素。我们利用 2017 年至 2021 年期间对美国爱荷华州 128 个湖泊采样的夏季监测数据,建立并评估了一个微囊藻毒素检测预测模型,该模型是湖泊物理和化学属性、流域特征、浮游动物丰度和天气的函数。根据 2017 年数据建立的模型确定了 pH 值、总营养浓度和生态地理变量是该湖泊群体中微囊藻毒素检测的最佳预测因子。然后,我们将 2017 年的分类模型应用于随后几年收集的数据,发现模型的技能有所下降,但仍能有效预测微囊藻毒素的检测(曲线下面积,AUC ≥ 0.7)。我们评估了是否可以通过将前几年的监测数据同化到模型中来提高分类技能,但模型技能的提高微乎其微。总体而言,在不同的气候条件下,分类模型仍然是可靠的。最后,我们测试了能否将早期季节观测数据与训练有素的模型相结合,为夏末微囊藻毒素检测提供预警,但所有年份的模型技能都很低,有两年低于 AUC 临界值。这些建模工作的结果支持将基于单季采样数据的相关分析应用于监测决策,但还需要在其他地区进行类似的调查,以进一步证明这种方法在管理应用中的有效性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
An evaluation of statistical models of microcystin detection in lakes applied forward under varying climate conditions

Algal blooms can threaten human health if cyanotoxins such as microcystin are produced by cyanobacteria. Regularly monitoring microcystin concentrations in recreational waters to inform management action is a tool for protecting public health; however, monitoring cyanotoxins is resource- and time-intensive. Statistical models that identify waterbodies likely to produce microcystin can help guide monitoring efforts, but variability in bloom severity and cyanotoxin production among lakes and years makes prediction challenging. We evaluated the skill of a statistical classification model developed from water quality surveys in one season with low temporal replication but broad spatial coverage to predict if microcystin is likely to be detected in a lake in subsequent years. We used summertime monitoring data from 128 lakes in Iowa (USA) sampled between 2017 and 2021 to build and evaluate a predictive model of microcystin detection as a function of lake physical and chemical attributes, watershed characteristics, zooplankton abundance, and weather. The model built from 2017 data identified pH, total nutrient concentrations, and ecogeographic variables as the best predictors of microcystin detection in this population of lakes. We then applied the 2017 classification model to data collected in subsequent years and found that model skill declined but remained effective at predicting microcystin detection (area under the curve, AUC ≥ 0.7). We assessed if classification skill could be improved by assimilating the previous years’ monitoring data into the model, but model skill was only minimally enhanced. Overall, the classification model remained reliable under varying climatic conditions. Finally, we tested if early season observations could be combined with a trained model to provide early warning for late summer microcystin detection, but model skill was low in all years and below the AUC threshold for two years. The results of these modeling exercises support the application of correlative analyses built on single-season sampling data to monitoring decision-making, but similar investigations are needed in other regions to build further evidence for this approach in management application.

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来源期刊
Harmful Algae
Harmful Algae 生物-海洋与淡水生物学
CiteScore
12.50
自引率
15.20%
发文量
122
审稿时长
7.5 months
期刊介绍: This journal provides a forum to promote knowledge of harmful microalgae and macroalgae, including cyanobacteria, as well as monitoring, management and control of these organisms.
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