Croteau Kelly, Ryan Adam C, Santore Robert, DeForest David, Schlekat Christian, Middleton Elizabeth, Garman Emily
Windward Environmental, Syracuse, New York, USA.
International Zinc Association, Durham, North Carolina, USA.
Environ Toxicol Chem. 2021 Aug;40(8):2189-2205. doi: 10.1002/etc.5063. Epub 2021 Jul 7.
Toxicity-modifying factors can be modeled either empirically with linear regression models or mechanistically, such as with the biotic ligand model (BLM). The primary factors affecting the toxicity of nickel to aquatic organisms are hardness, dissolved organic carbon (DOC), and pH. Interactions between these terms were also considered. The present study develops multiple linear regressions (MLRs) with stepwise regression for 5 organisms in acute exposures, 4 organisms in chronic exposures, and pooled models for acute, chronic, and all data and compares the performance of the Pooled All MLR model to the performance of the BLM. Independent validation data were used for evaluating model performance, which for pooled models included data for organisms and endpoints not present in the calibration data set. Hardness and DOC were most often selected as the explanatory variables in the MLR models. An attempt was also made at evaluating the uncertainty of the predictions for each model; predictions that showed the most error tended to show the highest levels of uncertainty as well. The performances of the 2 models were largely equal, with differences becoming more apparent when looking at the performance within subsets of the data. Environ Toxicol Chem 2021;40:2189-2205. © 2021 SETAC.
毒性修正因子可以通过线性回归模型进行经验建模,也可以通过机理模型进行建模,例如生物配体模型(BLM)。影响镍对水生生物毒性的主要因素是硬度、溶解有机碳(DOC)和pH值。还考虑了这些因素之间的相互作用。本研究针对急性暴露中的5种生物、慢性暴露中的4种生物开发了逐步回归的多元线性回归(MLR)模型,以及针对急性、慢性和所有数据的合并模型,并将合并所有MLR模型的性能与BLM的性能进行了比较。使用独立验证数据来评估模型性能,对于合并模型,这些数据包括校准数据集中不存在的生物和终点的数据。硬度和DOC最常被选为MLR模型中的解释变量。还尝试评估每个模型预测的不确定性;误差最大的预测往往也显示出最高水平的不确定性。这两种模型的性能在很大程度上是相等的,在查看数据子集内的性能时差异变得更加明显。《环境毒理学与化学》2021年;40:2189 - 2205。© 2021 SETAC。
