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Ecotoxicological information

Long-term toxicity to aquatic invertebrates

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The chronic toxicity to aquatic invertebrates of the oil as a whole substance was predicted to be 0.0135 mg/l (Chronic Value), based on the expected additive effect of the two nitrile components of the oil (at a concentration of 4 % w/w of the oil).

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Additional information

Using QSAR models it was found that the nitrile fraction of the oil drives the chronic aquatic toxicity of the substance more than the hydrocarbon fraction. The potential aquatic toxicity of the non-hydrocarbon components of the UVCB was determined via a literature search for applicable data on the substances. The only non-hydrocarbon components in the substance that have significantly greater toxicity than the hydrocarbon elements are the two nitriles, hexadecanoic acid and eicodecanoic acid. These components make up a combined fraction of 1.7 % w/w of the substance. If the recommended assessment factors applied to the nitriles the toxicity of the overall substance will be mainly due to the nitriles. Therefore the PNEC of the substance will be based on the nitrile content of the substance. The chronic toxicity of the nitrile fraction of the substance to aquatic invertebrates was calculated using the ECOSAR model (v 1.11), which was developed by the US EPA and uses a database of measured data to calculate the baseline ecotoxicity of organic compounds. The model calculates the baseline toxicity of a substance by assuming that the substance behaves as a narcotic and the toxicity is correlated to the partition co-efficient. It then highlights functional groups that have been shown to display excess toxicity. Neither nitrile contains functional groups that display excess toxicity and are therefore viewed as “neutral organics”. The chronic toxicity to aquatic invertebrates of the oil as a whole substance was predicted to be 0.0135 mg/l (Chronic Value), based on the expected additive effect of the two nitrile components of the oil (at a concentration of 4 % w/w of the oil).

The chronic toxicity to fish of the hydrocarbon fraction of the UVCB substance Thermal cracking oil from blends of rubber, fuel oils and paraffin waxes, steam-stripped, was calculated using the PETROTOX model, made available by CONCAWE, which uses the Hydrocarbon Block Model to predict the eco-toxicological endpoints. The default systems parameters of PETROTOX are designed to mimic the design of typical experimental systems. Therefore the simulations were performed assuming a 10% headspace volume to account for volatilization of some components. Additionally the particulate organic carbon loading was set at 2 mg/L for algae and SSTP organisms, whereas it was left at 0 mg/L for the fish and daphnia models. It is assumed that the presence of organic carbon would result in the absorption of some of the test substance and hence lower the bioavailability. This approach was consistent with the initial validation of the model. The output of the PETROTOX model gives “Toxic Unit” (TU) values at different loadings that are converted to an LD50. This acute toxicity value is then converted to the chronic NOEL using standard acute to chronic ratios. The 21 day NOEC of the hydrocarbon fraction of the UVCB to aquatic invertebrates was estimated to be 0.18 mg/l using PetroTox.