Passive sampling methods for contaminated sediments: Scientific rationale supporting use of freely dissolved concentrations

Mayer, Philipp; Parkerton, Thomas F.; Adams, Rachel G.; Cargill, John G; Gan, Jay; Gouin, Todd; Gschwend, Philip M.; Hawthorne, Steven B.; Helm, Paul A.; Witt, Gesine; You, Jing; Escher, Beate I.

doi:10.1002/ieam.1508

Cited by 154 publications

(130 citation statements)

References 91 publications

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“…Initially the limit identified in Equation 1 was parameterized at log K OW of 6 [9,[40][41][42][43], which effectively reduced the bioavailability of more hydrophobic components while allowing fractional contribution to overall toxicity of the substance to be included in P TU calculations [44][45][46]. This nonlinear partitioning behavior may reflect the impact of low solubility and slow toxicokinetics [47] or other competing processes that limit accumulation in the target lipid for these low-solubility constituents.…”

Section: Modeling Analysismentioning

confidence: 99%

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

Redman

Parkerton

Paumen³

et al. 2017

Enviro Toxic and Chemistry

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The PETROTOX model was developed to perform aquatic hazard assessment of petroleum substances based on substance composition. The model relies on the hydrocarbon block method, which is widely used for conducting petroleum substance risk assessments providing further justification for evaluating model performance. Previous work described this model and provided a preliminary calibration and validation using acute toxicity data for limited petroleum substance. The objective of the present study was to re-evaluate PETROTOX using expanded data covering both acute and chronic toxicity endpoints on invertebrates, algae, and fish for a wider range of petroleum substances. The results indicated that recalibration of 2 model parameters was required, namely, the algal critical target lipid body burden and the log octanol-water partition coefficient (K ) limit, used to account for reduced bioavailability of hydrophobic constituents. Acute predictions from the updated model were compared with observed toxicity data and found to generally be within a factor of 3 for algae and invertebrates but overestimated fish toxicity. Chronic predictions were generally within a factor of 5 of empirical data. Furthermore, PETROTOX predicted acute and chronic hazard classifications that were consistent or conservative in 93 and 84% of comparisons, respectively. The PETROTOX model is considered suitable for the purpose of characterizing petroleum substance hazard in substance classification and risk assessments. Environ Toxicol Chem 2017;36:2245-2252. © 2017 SETAC.

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Section: Modeling Analysismentioning

confidence: 99%

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

Redman

Parkerton

Paumen³

et al. 2017

Enviro Toxic and Chemistry

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“…After the 33 day exposure, mussels were recovered, returned to the laboratory in coolers on ice, frozen at -4 ºC, 281 and stored in the dark until chemical analysis. where, k e is the PRC transfer coefficient (1/day) and t (day) the duration of the deployment: where, C lipid is the lipid-normalized PCB concentration measured in the mussel tissues [5]. other treatments while C free based on SPME and total water were not different, total water and 355 SPMD C free were also not different, and, finally, SPMD and C 18 -based C free were not different.…”

mentioning

confidence: 99%

Application of passive sampling for measuring dissolved concentrations of organic contaminants in the water column at three marine superfund sites

Burgess

Lohmann

Schubauer‐Berigan

et al. 2015

Enviro Toxic and Chemistry

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“…As previously mentioned for PSDs in the water column, recent developments in PSMs have significantly improved our ability to reliably measure even very low levels of C free (Mayer et al, 2014). A brief overview of these five papers has been proposed by Parkenson and Maruya (2014), who emphasize the needs for future research and communication for future consensus among the science, management, and practitioners on the appropriate use of PSMs in supporting contaminated sediment management (Mayer et al, 2014). A brief overview of these five papers has been proposed by Parkenson and Maruya (2014), who emphasize the needs for future research and communication for future consensus among the science, management, and practitioners on the appropriate use of PSMs in supporting contaminated sediment management (Mayer et al, 2014).…”

Section: Chemical Monitoring In Sedimentmentioning

confidence: 99%

Quality Standard Setting and Environmental Monitoring

Amiard‐Triquet¹

2015

Aquatic Ecotoxicology

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Passive sampling methods for contaminated sediments: Scientific rationale supporting use of freely dissolved concentrations

Cited by 154 publications

References 91 publications

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

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

Application of passive sampling for measuring dissolved concentrations of organic contaminants in the water column at three marine superfund sites

Quality Standard Setting and Environmental Monitoring

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