Environmental quality criteria for organic chemicals predicted from internal effect concentrations and a food web model

Traas, Theo P.; Wezel, Annemarie P. van; Hermens, Joop L. M.; Zorn, Mathilde I.; Hattum, A.G.M. van; Leeuwen, Cornelis van

doi:10.1897/03-441

Cited by 27 publications

(29 citation statements)

References 55 publications

(178 reference statements)

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“…In addition, body burdens of specific chemicals in field‐collected organisms can be compared to known critical body residues derived from laboratory data, thus allowing prediction of risk of adverse effects. Traas et al (2004) coupled critical body residues to food web bioaccumulation models to develop environmental quality criteria that agree well, in most cases, with criteria based on data from toxicity testing. Thus, this method allows risk to be evaluated even when more traditional forms of bioaccumulation data for specific chemicals or components of the food web are lacking.…”

Section: Screening Assessmentmentioning

confidence: 99%

Evaluation of Bioaccumulation Using In Vivo Laboratory and Field Studies

Weisbrod

Woodburn

Koelmans

et al. 2009

Integr Envir Assess & Manag

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A primary consideration in the evaluation of chemicals is the potential for substances to be absorbed and retained in an organism's tissues (i.e., bioaccumulated) at concentrations sufficient to pose health concerns. Substances that exhibit properties that enable biomagnification in the food chain (i.e., amplification of tissue concentrations at successive trophic levels) are of particular concern due to the elevated long‐term exposures these substances pose to higher trophic organisms, including humans. Historically, biomarkers of in vivo chemical exposure (e.g., eggshell thinning, bill deformities) retrospectively led to the identification of such compounds, which were later categorized as persistent organic pollutants. Today, multiple bioaccumulation metrics are available to quantitatively assess the bioaccumulation potential of new and existing chemicals and identify substances that, upon or before environmental release, may be characterized as persistent organic pollutants. This paper reviews the various in vivo measurement approaches that can be used to assess the bioaccumulation of chemicals in aquatic or terrestrial species using laboratory‐exposed, field‐deployed, or collected organisms. Important issues associated with laboratory measurements of bioaccumulation include appropriate test species selection, test chemical dosing methods, exposure duration, and chemical and statistical analyses. Measuring bioaccumulation at a particular field site requires consideration of which test species to use and whether to examine natural populations or to use field‐deployed populations. Both laboratory and field methods also require reliable determination of chemical concentrations in exposure media of interest (i.e., water, sediment, food or prey, etc.), accumulated body residues, or both. The advantages and disadvantages of various laboratory and field bioaccumulation metrics for assessing biomagnification potential in aquatic or terrestrial food chains are discussed. Guidance is provided on how to consider the uncertainty in these metrics and develop a weight‐of‐evidence evaluation that supports technically sound and consistent persistent organic pollutant and persistent, bioaccumulative, and toxic chemical identification. Based on the bioaccumulation information shared in 8 draft risk profiles submitted for review under the United Nations Stockholm Convention, recommendations are given for the information that is most critical to aid transparency and consistency in decision making.

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Section: Screening Assessmentmentioning

confidence: 99%

Evaluation of Bioaccumulation Using In Vivo Laboratory and Field Studies

Weisbrod

Woodburn

Koelmans

et al. 2009

Integr Envir Assess & Manag

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“…It is evident that with an increasing solidswater ratio and partition coefficient, the fraction of the chemical in the solid phase of the system also increases. For a chemical with a K p value of 10 5 L/kg, only some 10% would be associated with the particles (typically 78 Transport, accumulation and transformation processes 10 mg/L on a dry weight basis, FR w = small) in surface water. In a typical soil system where FR w = FR s = 40%, only as little as 10 -6 % of the same chemical would be present in the water phase.…”

Section: Sediment-water Suspended Matter-water and Soilwater Equilibriamentioning

confidence: 99%

“…The great advantage of these models is that food webs of any dimension can be described with as many food sources as required, and concentrations in all species can be calculated simultaneously [76]. In general, food web models successfully predict steady-state concentrations of persistent halogenated organic pollutants which are slowly metabolized [77,78]. However, these models are still relatively difficult to use for screening a large number of chemicals.…”

Section: Bioaccumulation Modelsmentioning

confidence: 99%

Transport, Accumulation and Transformation Processes

Sijm¹,

Rikken²,

Rorije³

et al. 2007

Risk Assessment of Chemicals

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“…Variability is at least partly due to differences in the type of interval calculated (minimummaximum versus 90 percentile) and the substances and species included (4,5,69).…”

Section: Mode Of Action and Species Groupmentioning

confidence: 99%

Critical Body Residues Linked to Octanol−Water Partitioning, Organism Composition, and LC₅₀QSARs: Meta-analysis and Model

Hendriks

Traas

Huijbregts

2005

Environ. Sci. Technol.

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To protect thousands of species from thousands of chemicals released in the environment, various risk assessment tools have been developed. Here, we link quantitative structure-activity relationships (QSARs) for response concentrations in water (LC50) to critical concentrations in organisms (C50) by a model for accumulation in lipid or non-lipid phases versus water Kpw. The model indicates that affinity for neutral body components such as storage fat yields steep Kpw-Kow relationships, whereas slopes for accumulation in polar phases such as proteins are gentle. This pattern is confirmed by LC50 QSARs for different modes of action, such as neutral versus polar narcotics and organochlorine versus organophosphor insecticides. LC50 QSARs were all between 0.00002 and 0.2Kow(-1). After calibrating the model with the intercepts and, for the first time also, with the slopes of the LC50 QSARs, critical concentrations in organisms C50 are calculated and compared to an independent validation data set. About 60% of the variability in lethal body burdens C50 is explained by the model. Explanations for differences between estimated and measured levels for 11 modes of action are discussed. In particular, relationships between the critical concentrations in organisms C50 and chemical (Kow) or species (lipid content) characteristics are specified and tested. The analysis combines different models proposed before and provides a substantial extension of the data set in comparison to previous work. Moreover, the concept is applied to species (e.g., plants, lean animals) and substances (e.g., specific modes of action) that were scarcely studied quantitatively so far.

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Environmental quality criteria for organic chemicals predicted from internal effect concentrations and a food web model

Cited by 27 publications

References 55 publications

Evaluation of Bioaccumulation Using In Vivo Laboratory and Field Studies

Evaluation of Bioaccumulation Using In Vivo Laboratory and Field Studies

Transport, Accumulation and Transformation Processes

Critical Body Residues Linked to Octanol−Water Partitioning, Organism Composition, and LC₅₀QSARs: Meta-analysis and Model

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Environmental quality criteria for organic chemicals predicted from internal effect concentrations and a food web model

Cited by 27 publications

References 55 publications

Evaluation of Bioaccumulation Using In Vivo Laboratory and Field Studies

Evaluation of Bioaccumulation Using In Vivo Laboratory and Field Studies

Transport, Accumulation and Transformation Processes

Critical Body Residues Linked to Octanol−Water Partitioning, Organism Composition, and LC50QSARs: Meta-analysis and Model

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Product

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Critical Body Residues Linked to Octanol−Water Partitioning, Organism Composition, and LC₅₀QSARs: Meta-analysis and Model