A re‐evaluation of PETROTOX for predicting acute and chronic toxicity of petroleum substances

Redman, Aaron D.; Parkerton, Thomas F.; Paumen, Miriam Leόn; Butler, Josh D.; Letinski, Daniel J.; Haan, Klass den

doi:10.1002/etc.3744

Cited by 45 publications

(25 citation statements)

References 40 publications

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“…In some cases, the differences between predicted and experimentally determined chronic aquatic toxicity could be 2-3 orders of magnitude. Evidence of the conservative nature of the PETROTOX model in the prediction of chronic aquatic toxicity of petroleum products can be found in a recent assessment by Redman et al (2017). In this study, the researchers found that chronic aquatic toxicity predictions for petroleum products were generally within a factor of 5 of empirical data.…”

Section: Prediction Of Gtl Ecotoxicity Endpointsmentioning

confidence: 58%

Toxicological and ecotoxicological properties of gas-to-liquid (GTL) products. 2. Ecotoxicology

Whale

Dawick

Hughes

et al. 2018

Critical Reviews in Toxicology

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Gas-to-liquid (GTL) products are synthetic hydrocarbons produced from natural gas using a catalytic process known as the Fischer-Tropsch process. This process yields a synthetic crude oil that consists of saturated hydrocarbons which can subsequently be refined to a range of products analogous to those obtained from petroleum refining. However, in contrast to their petroleum-derived analogs, GTL products are essentially free of unsaturated or aromatic compounds and do not contain any sulfur-, oxygen-, or nitrogen-containing compounds. Under new chemical substance notification requirements, an extensive testing program covering the entire portfolio of GTL products has been undertaken to assess their hazardous properties to human health and environment. The results of these studies have been summarized in a two-part review. Part 1 provides an overview of the mammalian toxicity hazardous properties of the various GTL products. This second part of the review focuses on the aquatic, sediment, terrestrial, and avian toxicity studies which assess the ecotoxicological hazard profile of the GTL products. Many challenges were encountered during these tests relating to dosing, analysis and interpretation of results. These are discussed with the intent to share experiences to help inform and shape future regulatory mandates for testing of poorly soluble complex substances. As was the case with the mammalian toxicology review, there were a few cases where adverse effects were found, but overall the GTL products were found to exert minimal adverse ecotoxicological effects and these were less severe than effects observed with their conventional, petroleum-derived analogs.

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Section: Prediction Of Gtl Ecotoxicity Endpointsmentioning

confidence: 58%

Toxicological and ecotoxicological properties of gas-to-liquid (GTL) products. 2. Ecotoxicology

Whale

Dawick

Hughes

et al. 2018

Critical Reviews in Toxicology

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“…The TLM was originally derived for a set of known narcotic chemicals (n = 140) and test organisms (sp = 33) (Di but has since been expanded and revised to include additional species (McGrath et al, 2004), additional classes of petroleum products (i.e., gasoline constituents, mono-and polycyclic aromatic hydrocarbons) (McGrath et al, 2005;McGrath and Di Toro, 2009), and additional environmental compartments (i.e., soil and sediment) (Redman et al 2014b). The TLM forms the basis for the PET-ROTOX and PETRORISK tools, widely used in hazard and exposure assessments for petroleum hydrocarbon products and hydrocarbon solvents in North America and the European Union (EU) (Redman et al, 2012;Redman et al, 2014a;Redman et al, 2017).…”

Section: Target Lipid Modelmentioning

confidence: 99%

Biodegradation and Ecotoxicity of Branched Alcohol Ethoxylates: Application of the Target Lipid Model and Implications for Environmental Classification

Bragin

Davis

Kung

et al. 2019

J Surfact & Detergents

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With the advent of global regulations for safer detergent and an emphasis on a shift toward more environmentally friendly formulations, the environmental profile of surfactant chemistries have moved to the forefront of product formulation and design. The two cornerstones of surfactant environmental profiles are the ability to biodegrade in the natural environment and the ecological hazard profile. The objectives of this article are to describe biodegradation and aquatic toxicity data for a series of branched oxo‐alcohol ethoxylate (AEO) surfactants; to apply the target lipid model (TLM) for deriving model‐based threshold hazard concentrations (HC5) of AEO; and, finally, to accurately determine aquatic classifications for AEO surfactants for use in regulatory classification frameworks. Biodegradation results indicate a high level of biodegradability of branched AEO, with C8–C13‐rich oxo‐alcohols with 1–20 mol of ethoxylate meeting the readily biodegradable criteria. Results from acute and chronic toxicity tests indicated comparable or lesser aquatic toxicity versus linear AEO structures previously reported in the literature. The TLM model, applied a priori, resulted in good agreement with acute toxicity data (RMSE = 0.49) and is comparable to the root mean square errors (RMSE) previously determined for other narcotic chemicals (RMSE = 0.46–0.57). Model errors for invertebrates and fish were smaller than those for algae, with the TLM systematically overpredicting acute and chronic classification of two of seven branched AEO. Furthermore, TLM‐predicted HC5 values were determined to be sufficiently conservative, with 100% of observed chronic data (N = 79) falling above the HC5 threshold values, providing a useful tool for the risk assessment of AEO.

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“…Passive dosing has an advantage over traditional dosing methods in maintaining well‐controlled exposures that do not exceed solubility limits of individual or multiconstituent substances. Recent studies have applied this concept by adding test oil into medical‐grade silicone tubing, which is then introduced into the aqueous test media to produce a WAF (Kang et al ; Redman et al ). A second passive dosing format involves application of silicone O‐rings.…”

Section: Introductionmentioning

confidence: 99%

Passive dosing yields dissolved aqueous exposures of crude oil comparable to the CROSERF (Chemical Response to Oil Spill: Ecological Effects Research Forum) water accommodated fraction method

Bera

Parkerton

Redman

et al. 2018

Enviro Toxic and Chemistry

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The Chemical Response to Oil Spill: Ecological Effects Research Forum's water accommodated fraction procedure was compared with 2 alternative techniques in which crude oil was passively dosed from silicone tubing or O-rings. Fresh Macondo oil (MC252) was dosed at 30 mg/L using each approach to investigate oil dissolution kinetics, which was monitored by fluorometry as estimated oil equivalents (EOEs). Subsequent experiments with each dosing method were then conducted at multiple oil loadings. Following equilibration, test media were analytically characterized for polyaromatic hydrocarbons (PAHs) using gas chromatography (GC)-mass spectrometry and dissolved oil using biomimetic solid-phase microextraction (SPME). The results showed that equilibrium was achieved within 72 h for all methods. Measured PAH concentrations were compared with oil solubility model predictions of dissolved exposures. The concentration and composition of measured and predicted dissolved PAHs varied with oil loading and were consistent between dosing methods. Two-dimensional GC compositional data for this oil were then used to calculate dissolved toxic units for predicting MC252 oil acute toxicity across the expected range of species sensitivities. Predicted toxic units were nonlinear with loading and correlated to both EOE and biomimetic SPME. Passive dosing methods provide a practical strategy to deliver and maintain dissolved oil concentrations while avoiding the complicating role that droplets can introduce in exposure characterization and test interpretation. Environ Toxicol Chem 2018;37:2810-2819. © 2018 SETAC.

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A re‐evaluation of PETROTOX for predicting acute and chronic toxicity of petroleum substances

Cited by 45 publications

References 40 publications

Toxicological and ecotoxicological properties of gas-to-liquid (GTL) products. 2. Ecotoxicology

Toxicological and ecotoxicological properties of gas-to-liquid (GTL) products. 2. Ecotoxicology

Biodegradation and Ecotoxicity of Branched Alcohol Ethoxylates: Application of the Target Lipid Model and Implications for Environmental Classification

Passive dosing yields dissolved aqueous exposures of crude oil comparable to the CROSERF (Chemical Response to Oil Spill: Ecological Effects Research Forum) water accommodated fraction method

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