Irstea, UR MALY, Centre de Lyon-Villeurbanne, 5 rue de la Doua, CS 20244, F-69625 Villeurbanne Cedex, France.
Irstea, UR EABX, Centre de Bordeaux, 50 avenue de Verdun, F-33612 Cestas Cedex, France.
Sci Total Environ. 2018 Feb 15;615:197-207. doi: 10.1016/j.scitotenv.2017.08.311. Epub 2017 Sep 29.
The "pharmaceutical" polar organic integrative sampler (POCIS) is a passive sampler composed of an outer polyethersulfone (PES) membrane and an inner receiving Hydrophilic-Lipophilic Balance (HLB) phase. Target micropollutants can accumulate in the POCIS HLB phase following different uptake patterns. Two of the most common ones are a first-order kinetic uptake (Chemical Reaction Kinetic 1, CRK1 model), and a first-order kinetic uptake with an inflexion point (CRK2 model). From a previous study, we identified 30 and 13 micropollutants following CRK1 and CRK2 accumulation model in the POCIS HLB phase, respectively. We hypothesized that uptake in the outer PES membrane of POCIS may influence the uptake pathway. Thus, novel measurements of uptake in PES membrane were performed for these micropollutants to characterise kinetic accumulation in the membrane with and without the HLB phase. We determined, for the first time, the membrane-water distribution coefficient for 31 micropolluants. Moreover, the lag times for molecules to breakthrough the POCIS membrane increased with increasing hydrophobicity, defined by the octanol-water dissociation constant D. However, D alone was insufficient to predict whether uptake followed a CRK1 or CRK2 model in the POCIS HLB phase. Thus, we performed a factorial discriminant analysis considering several molecular physico-chemical properties, and the model of accumulation for the studied micropollutants can be predicted with >90% confidence. The most influent properties to predict the accumulation model were the log D and the polar surface area of the molecule (>70% confidence with just these two properties). Molecules exhibiting a CRK1 uptake model for the POCIS HLB phase tended to have log D>2.5 and polar surface area <50Ǻ.
“药物”型的极性有机整合采样器(POCIS)是一种由外聚醚砜(PES)膜和内亲水 - 疏水平衡(HLB)相组成的被动采样器。目标微量污染物可以按照不同的吸收模式在 POCIS HLB 相中积累。其中最常见的两种模式是一级动力学吸收(化学反应动力学 1,CRK1 模型)和带有拐点的一级动力学吸收(CRK2 模型)。在之前的研究中,我们分别在 POCIS HLB 相中识别出 30 种和 13 种按照 CRK1 和 CRK2 积累模型积累的微量污染物。我们假设 POCIS 外 PES 膜的吸收可能会影响吸收途径。因此,我们对这些微量污染物在外 PES 膜中的吸收进行了新的测量,以描述在有和没有 HLB 相的情况下在膜中的动力学积累。我们首次确定了 31 种微量污染物的膜 - 水分配系数。此外,分子穿透 POCIS 膜的滞后时间随着疏水性的增加而增加,疏水性由辛醇 - 水离解常数 D 定义。然而,D 本身不足以预测微量污染物在 POCIS HLB 相中是按照 CRK1 还是 CRK2 模型吸收。因此,我们考虑了几个分子物理化学性质进行了因子判别分析,并且可以用 >90%的置信度预测研究微量污染物的积累模型。预测积累模型的最具影响力的性质是分子的 log D 和极性表面积(仅使用这两个性质就有>70%的置信度)。在 POCIS HLB 相中表现出 CRK1 吸收模式的分子倾向于具有 log D>2.5 和极性表面积 <50Ǻ。
