The sensitivity of a deep-sea fish species (Anoplopoma fimbria) to oil-associated aromatic compounds, dispersant, and Alaskan North Slope crude oil.
Megan M McConvilleJohn P RobertsMyrina BoulaisBenjamin WoodallJoshua D ButlerAaron D RedmanThomas F ParkertonW Ray ArnoldJulian GuyomarchStéphane LeFlochJenny BytingsvikLionel CamusAswani VoletySusanne M BranderPublished in: Environmental toxicology and chemistry (2018)
A predominant concern following oil spills is toxicity to aquatic organisms. However, few data are available on effects in deep-sea cold water fishes. The present study had 3 major objectives. The first was to investigate the relative sensitivity of the deep-sea species Anoplopoma fimbria (sablefish) to acute effects of 3 aromatic compounds (toluene, 2-methylnaphthalene, and phenanthrene), dispersant alone, and chemically enhanced water accommodated fractions (CEWAFs) of Alaskan North Slope crude oil. The second was to determine the critical target lipid body burden (CTLBB) for sablefish by fitting aromatic hydrocarbon toxicity data to the target lipid model (TLM), which then allowed expression of CEWAF exposures in terms of dissolved oil toxic units. The final aim was to apply a passive sampling method that targets bioavailable, dissolved hydrocarbons as an alternative analytical technique for improved CEWAF exposure assessment. The results indicate that sablefish exhibit sensitivity to Corexit 9500 (96-h median lethal concentration [LC50] = 72.2 mg/L) within the range reported for other fish species. However, the acute CTLBB of 39.4 ± 2.1 μmol/goctanol lies at the lower end of the sensitivity range established for aquatic species. The utility of both toxic units and passive sampling measurements for describing observed toxicity of dispersed oil is discussed. The present study is novel in that a new test species is investigated to address the uncertainty regarding the sensitivity of deep-sea fishes, while also employing modeling and measurements to improve exposure characterization in oil toxicity tests. Environ Toxicol Chem 2018;37:2210-2221. © 2018 SETAC.
Keyphrases
- fatty acid
- oxidative stress
- liver failure
- risk assessment
- electronic health record
- genetic diversity
- amino acid
- mass spectrometry
- poor prognosis
- air pollution
- drug induced
- oxide nanoparticles
- gram negative
- high resolution
- data analysis
- extracorporeal membrane oxygenation
- artificial intelligence
- high resolution mass spectrometry
- gas chromatography