Reverse quantitative structure–activity relationship for modelling the sorption of esfenvalerate to dissolved organic matter: A multivariate approach

The sorption of the pyrethroid, esfenvalerate, to the dissolved and/or dispersed fraction of eight different natural humic compounds has been investigated. The dissolved organic matters (DOMs) included in this study originate from ground water, soil pore water, and surface waters. Sorption was model...

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Published in:Chemosphere (Oxford) 2002-12, Vol.49 (10), p.1317-1325
Main Authors: Thomsen, Marianne, Dobel, Shima, Lassen, Pia, Carlsen, Lars, Bügel Mogensen, Betty, Erik Hansen, Poul
Format: Article
Language:English
Subjects:
Adsorption
Applied sciences
Biological and physicochemical phenomena
Dissolved and/or dispersed organic matter
Earth sciences
Earth, ocean, space
Engineering and environment geology. Geothermics
Equilibrium partitioning coefficient
Esfenvalerate
Exact sciences and technology
Freshwater
Humic Substances
Insecticides - chemistry
KDOM
Models, Theoretical
Natural water pollution
Nitriles
Pollution
Pollution, environment geology
Pyrethrins - chemistry
Reverse QSAR
Solubility
Structure-Activity Relationship
Water treatment and pollution
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container_start_page 1317
container_title Chemosphere (Oxford)
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creator Thomsen, Marianne
Dobel, Shima
Lassen, Pia
Carlsen, Lars
Bügel Mogensen, Betty
Erik Hansen, Poul
description The sorption of the pyrethroid, esfenvalerate, to the dissolved and/or dispersed fraction of eight different natural humic compounds has been investigated. The dissolved organic matters (DOMs) included in this study originate from ground water, soil pore water, and surface waters. Sorption was modelled at DOM concentration levels where equilibrium partitioning of esfenvalerate between DOM and the aqueous bulk phase prevails. The inherent characteristics of the eight different humic materials, quantified in the preceding paper by Thomsen et al. (2002, this issue (PII: S0045-6535(02)00335-1)), have been used as explanatory variables for modelling this equilibrium partitioning. Using a reverse QSAR approach based on by projection-into-latent-structure regression (PLS-R) inherent sorbent properties determining for the sorption affinity of esfenvalerate to DOM were analysed. For all humic substances a decrease in the DOM-normalised equilibrium-partitioning coefficient, K DOM, with increasing concentration of DOM was observed. Significant variations in K DOM values, as function of the inherent characteristics of the individual humic substances, were found at DOM concentrations of 75 and 100 ppm, respectively. The latter is a strong indication of variations in sorption mechanisms of esfenvalerate to DOM of varying inherent properties. Groupings in the principal property space quantifying DOMs may indicate that separate models are needed for quantifying the equilibrium partitioning to different classes of DOM.
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ispartof Chemosphere (Oxford), 2002-12, Vol.49 (10), p.1317-1325
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1879-1298
language eng
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source ScienceDirect Journals
subjects Adsorption
Applied sciences
Biological and physicochemical phenomena
Dissolved and/or dispersed organic matter
Earth sciences
Earth, ocean, space
Engineering and environment geology. Geothermics
Equilibrium partitioning coefficient
Esfenvalerate
Exact sciences and technology
Freshwater
Humic Substances
Insecticides - chemistry
KDOM
Models, Theoretical
Natural water pollution
Nitriles
Pollution
Pollution, environment geology
Pyrethrins - chemistry
Reverse QSAR
Solubility
Structure-Activity Relationship
Water treatment and pollution
title Reverse quantitative structure–activity relationship for modelling the sorption of esfenvalerate to dissolved organic matter: A multivariate approach
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