Analysis of Sublethal Toxicity in Developing Zebrafish Embryos Exposed to a Range of Petroleum Substances

Hedgpeth, Bryan M.; Redman, Aaron D.; Alyea, Rebecca A.; Letinski, Daniel J.; Connelly, Martin J.; Butler, Josh D.; Zhou, Heping; Lampi, Mark A.

doi:10.1002/etc.4428

Cited by 16 publications

(9 citation statements)

References 65 publications

(136 reference statements)

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“…The results showed that the relative species sensitivity of Lymnaea stagnalis (log CTLBB = 1.83 µmol/g lipid) is close to the mean of 14 tested aquatic species (log CTLBBs = 1.85 µmol/g lipid), including invertebrates, algae, and bacteria [30]. A biomimetic extraction method by solid-phase microextraction (BE-SPME) has been developed to predict toxicity during exposure to complex organic mixtures [31]. Pairing BE-SPME analysis results with toxicity response/endpoints of snails could validate this screening tool for estimating the toxicity of OSPW in the future.…”

Section: Bioindicatormentioning

confidence: 99%

The Appropriateness of Using Aquatic Snails as Bioindicators of Toxicity for Oil Sands Process-Affected Water

Chen¹,

Eaton²,

Davies³

2021

Pollutants

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Canada’s oil sands mining activity produces large volumes of oil sands process-affected water (OSPW), and there have been increasing concerns regarding the potential environmental impacts associated with this material. Developing an understanding of the toxicity of OSPW is critical to anticipating and mitigating the potential risks and effects of the oil sands industry on surrounding ecosystems. The composition of OSPW is highly variable and is influenced by a range of factors. While numerous research projects have been conducted on the toxicity of OSPW, much remains unknown about its impact on various biota. Freshwater gastropods (snails and slugs) are an ecologically crucial aquatic group, and members of this taxa have been used as bioindicators in a range of ecological settings. The literature suggests freshwater snails could be used as an indicator of toxicity in monitoring programs associated with oil sands development. This mini-review explores the use of snails as bioindicators in aquatic systems affected by oil sands development, focusing on how snails may respond to potential constituents of concern in systems exposed to OSPW.

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Section: Bioindicatormentioning

confidence: 99%

The Appropriateness of Using Aquatic Snails as Bioindicators of Toxicity for Oil Sands Process-Affected Water

Chen¹,

Eaton²,

Davies³

2021

Pollutants

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“…The key to establishing nondepletive extraction conditions is to employ a low PDMS to water ratio (Redman, Butler, et al, 2018). The BE‐SPME method has the potential to simplify aquatic hazard assessments of petroleum substances and aid in establishing water quality criteria in receiving waters because the total moles of hydrocarbons sorbed into the fiber can be related to toxicity thresholds in target lipid of aquatic organisms (Hedgpeth et al, 2019).…”

Section: Introductionmentioning

confidence: 99%

Interlaboratory Comparison of a Biomimetic Extraction Method Applied to Oil Sands Process–Affected Waters

Letinski

Bekele

Connelly

2022

Enviro Toxic and Chemistry

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Biomimetic extraction using solid‐phase microextraction is a passive sampling analytical method that can predict the aquatic toxicity of complex petroleum substances. The method provides a nonanimal alternative to traditional bioassays with the potential to reduce both vertebrate and invertebrate aquatic toxicity testing. The technique uses commercially available polydimethylsiloxane‐coated fibers that, following nondepletive extraction of water samples, are injected into a gas chromatograph with flame ionization detection. As the predictive nature of the method is operationally defined, it is critical that its application be harmonized with regard to extraction, analysis, and standardization parameters. Results are presented from a round robin program comparing the results from 10 laboratories analyzing four different sample sets of dissolved organics in water. Samples included two incurred oil sands process–affected waters and a cracked gas oil water accommodated fraction. A fourth sample of cracked gas oil blended in an oil sands process–affected water was analyzed to demonstrate the method's ability to differentiate between neutral and ionizable dissolved hydrocarbons. Six of the 10 laboratories applied an automated version of the method using a robotic autosampler where the critical extraction steps are precisely controlled and which permits batch screening of water samples for aquatic toxicity potential. The remaining four laboratories performed the solid‐phase microextraction manually. The automated method demonstrated good reproducibility with between‐laboratory variability across the six laboratories and four samples yielding a mean relative standard deviation of 14%. The corresponding between‐laboratory variability across the four laboratories applying the manual extraction was 53%, demonstrating the importance of precisely controlling the extraction procedure. Environ Toxicol Chem 2022;41:1613–1622. © 2022 The Authors. Environmental Toxicology and Chemistry published by Wiley Periodicals LLC on behalf of SETAC.

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“…In the present study, we looked at a broader range of organismal sublethal effects that can be plausibly linked to narcosis and are potentially more sensitive than the ones used in previous studies: general morphological malformations (Hedgpeth et al, 2019; Vignet et al, 2014), oxygen consumption (Raftery et al, 2017), heart rate (Incardona et al, 2004; Raftery et al, 2017), and swimming performance (Vignet et al, 2014). We exposed zebrafish embryos in an adapted fish embryo acute toxicity (FET) test, Organisation for Economic Co‐operation and Development (OECD) test guideline 236 (Organisation for Economic Co‐operation and Development, 2013) to 3 well‐known nonpolar NICs (phenanthrene [PHN], 1,3,5‐trichlorobenzene [TChB], and pentachlorobenzene [PChB]) with varying octanol–water partition coefficients (log K OW , describing lipophilicity, range 4.0–5.2).…”

Section: Introductionmentioning

confidence: 99%

“…Narcosis‐inducing chemicals (NICs) exert their toxicity by accumulating in the organism's lipid compartments and disrupting the molecular interactions in cellular membranes, resulting in depressed respiratory–cardiovascular activity, lethargy, loss of equilibrium, and, finally, death of the organism (Ankley et al, 2010; Geier et al, 2018; Incardona et al, 2004; McKim et al, 1987; Raftery et al, 2017; van Wezel & Opperhuizen, 1995). Exposure to NICs can be harmful to various aquatic species and may lead to a decrease in population fitness (Escher & Hermens, 2002; Hedgpeth et al, 2019). Mortality resulting from exposure to NICs has been well described and discussed for different aquatic organisms, and acute toxicity data have been extensively used to develop quantitative structure–activity relationship models that predict mortality for aquatic organisms based on the lipophilicity of chemicals (Adhikari & Mishra, 2018; Di Toro et al, 2000; Finizio et al, 2020; Klüver et al, 2016).…”

Section: Introductionmentioning

confidence: 99%

“…A better understanding of the nature and incidence of such sublethal effects following exposure to NICs would thus be valuable in a risk-assessment context. For example, Hedgpeth et al (2019) recently drew attention to the importance of sublethal effects caused by petroleum substances (anthropogenic or natural mixtures), exerting toxicity mainly through narcosis. These authors focused on overt developmental abnormalities that are easily observable in zebrafish embryos and showed that morphological malformations occurred at approximately 2.8 times lower exposure concentrations compared to lethal effect concentrations.…”

Section: Introductionmentioning

confidence: 99%

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Sublethal Effect Concentrations for Nonpolar Narcosis in the Zebrafish Embryo

Massei

Knapen

Blust

et al. 2021

Enviro Toxic and Chemistry

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Nonpolar narcosis, also known as baseline toxicity, has been described as the minimal toxicity that an organic chemical may elicit based on its lipophilicity. Although lethal effects of narcosis-inducing chemicals (NICs) have been thoroughly investigated, knowledge of sublethal effects is still very limited. We investigated the effects of 3 well-known NICs (phenanthrene, 1,3,5-trichlorobenzene, and pentachlorobenzene) on a variety of organismal endpoints (malformations, swim bladder inflation, respiration, heart rate, swimming activity, and turning angles), which can be plausibly linked to narcosis in zebrafish embryos. Baseline toxicity recorded as mortality is typically observed in similar exposure ranges in a wide variety of species including fish, corresponding to a chemical activity range between 0.01 and 0.1. In the present study, we found that sublethal effects occurred at concentrations approximately 5 times below lethal concentrations. Altered swimming activity and impaired swim bladder inflation were the most sensitive endpoints occurring at exposure levels below the generally accepted threshold for baseline toxicity for 2 out of 3 compounds. Overall, most effective exposure levels across the sublethal endpoints and compounds did fall within the range typically associated with baseline toxicity, and deviations were generally limited to a factor 10. Although there could be benefit in adding sublethal endpoints to toxicity tests, such as the fish embryo acute toxicity (FET) test, based on the present sublethal endpoints and available evidence from our and other studies, the underestimation of toxicity as a result of the sole assessment of mortality as an endpoint in an FET test may be limited for narcosis.

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Analysis of Sublethal Toxicity in Developing Zebrafish Embryos Exposed to a Range of Petroleum Substances

Cited by 16 publications

References 65 publications

The Appropriateness of Using Aquatic Snails as Bioindicators of Toxicity for Oil Sands Process-Affected Water

The Appropriateness of Using Aquatic Snails as Bioindicators of Toxicity for Oil Sands Process-Affected Water

Interlaboratory Comparison of a Biomimetic Extraction Method Applied to Oil Sands Process–Affected Waters

Sublethal Effect Concentrations for Nonpolar Narcosis in the Zebrafish Embryo

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