How do water matrices influence QSPR models in wastewater treatment?–A case study on the sonolytic elimination of phenol derivates

PLOS water Pub Date : 2023-11-14 DOI:10.1371/journal.pwat.0000201

Judith Glienke, Michael Stelter, Patrick Braeutigam

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Abstract

As the demand of freshwater increases with simultaneously aggravated climatic challenges, the development of efficient and effective water purification methods is of high importance. Qualitative Structure-Property Relationships (QSPRs) can support this process by calculating a correlation between the molecular structure and the degradability of water pollutants in a defined removal procedure, expressed by the kinetic constant of their removal. This can help to receive more mechanistical interpretation of the underlying process, but also to reduce experimental costs and time. As most QSPR models in wastewater treatment research are based on experimental data using ultrapure water as reaction solutions, it is still unknown to which extent QSPR models for different water matrices differ from each other with regard to selected descriptors and performance. Therefore, in this study the sonolytic degradation of 32 phenol derivates was investigated for three different water matrices (NaCl, Glucose, NaCl+Glucose) and compared to a previous study in ultrapure water. With only very few exceptions, the addition of water additives reduced the degradability of the target analytes. Based on these four datasets, QSPR modelling, respecting all five OECD principles for reliable QSPR models, were performed using numerous internal and external validations as well as statistical quality assurances to ensure good regression abilities as well as stability and predictivity. As the final four models were compared, it was observed that the descriptor selection and model calculation were highly impacted by the water additives. This was also confirmed when the descriptor pools of the best 10 models for each water composition were compared, as the descriptor pools were also highly dissimilar, indicating a shift in structural importance when changing the water composition. It could be shown that water matrices significantly influence the results of QSPR modelling even at very low concentrations of the matrix components.

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水基质如何影响废水处理中的QSPR模型?超声消解苯酚衍生物的案例研究

随着淡水需求的增加和气候挑战的加剧，开发高效的水净化方法是非常重要的。定性结构-性质关系(QSPRs)可以通过计算分子结构与水污染物在确定的去除过程中的可降解性之间的相关性来支持这一过程，该过程由去除的动力学常数表示。这有助于获得对潜在过程的更机械的解释，也可以减少实验成本和时间。由于废水处理研究中的大多数QSPR模型都是基于超纯水作为反应溶液的实验数据，不同水基质的QSPR模型在选择描述符和性能方面的差异程度尚不清楚。因此，本研究研究了32种苯酚衍生物在三种不同水基质(NaCl、葡萄糖、NaCl+葡萄糖)下的声解降解，并与之前在超纯水中的研究进行了比较。除了极少数例外，水添加剂的加入降低了目标分析物的可降解性。基于这四个数据集，QSPR建模遵循OECD关于可靠QSPR模型的所有五项原则，通过大量的内部和外部验证以及统计质量保证进行，以确保良好的回归能力、稳定性和预测性。通过对最后四种模型的比较，可以发现描述符的选择和模型的计算受到水添加剂的高度影响。当比较每种水成分的最佳10个模型的描述符池时，也证实了这一点，因为描述符池也高度不同，表明在改变水成分时结构重要性发生了变化。可以证明，即使在非常低浓度的基质成分下，水基质也会显著影响QSPR建模的结果。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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PLOS water

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