Hydrocarbons, C4, 1,3-butadiene-free, polymd., tetraisobutylene fraction, hydrogenated

The aquatic toxicity of was estimated using the Petrotox computer model, which combines a partitioning model used to calculate the aqueous concentration of hydrocarbon components as a function of substance loading with the Target Lipid Model used to calculate acute and chronic toxicity of non-polar narcotic chemicals. Petrotox computes toxicity based on the summation of the aqueous-phase concentrations of hydrocarbon block(s) that represent a hydrocarbon substance and membrane-water partitioning coefficients (K_MW) that describe the partitioning of the hydrocarbons between the water and organism. Results of computer modelling to estimate chronicity in a 21-day freshwater invertebrate study, based on reproduction, show that this substance will not produce toxicity at or below its maximum attainable water solubility.

The 21-day EL50s based on adult immobilization and reduction in reproduction were >5 mg/L loading. The 21-day No Observed Effect Loading Rates (NOELRs) based on adult immobilization and reduction in reproduction was 5 mg/L.

The study was performed to evaluate the toxicity of the water accomodated fraction (WAF) of the test substance to the daphnid, Daphnia magna, in a semi-static system for a 21-day period. The loading rates for this test were 1 mg/L and 5 mg/L. A control of laboratory dilution water was also tested. Individual WAFs were prepared by adding the appropriate amount of the test substance to 3.5 liters of BW3 in a 4 L size glass aspirator bottle. The mixtures were then stirred for approximately 24 hours on a magnetic stirplate with a Teflon coated stirbar. Stirring was initiated using a vortex of <10% of the static liquid depth (1.5 cm). Each vessel was stoppered to prevent loss of volatiles. After stirring, the WAF was removed from the outlet at the bottom of the vessel.

Four replicates chambers were prepared per treatment by completely filling the test chambers with WAF (no headspace). Samples were removed from each WAF and the control on day 0, 2, 5, 7, 14, and at termination (composite of the replicate test chambers) for chemical analysis by gas chromatography with flame ionization detection (GS-FID). The results of the analysis showed that the levels of the test substance were below the practical quantitation limit of 0.2 mg/L.

The aquatic toxicity of was estimated using the Petrotox computer model, which combines a partitioning model used to calculate the aqueous concentration of hydrocarbon components as a function of substance loading with the Target Lipid Model used to calculate acute and chronic toxicity of non-polar narcotic chemicals. Petrotox computes toxicity based on the summation of the aqueous-phase concentrations of hydrocarbon block(s) that represent a hydrocarbon substance and membrane-water partitioning coefficients (K_MW) that describe the partitioning of the hydrocarbons between the water and organism. Results of computer modelling to estimate chronicity in a 21-day freshwater invertebrate study, based on reproduction, show that this substance will not produce toxicity at or below its maximum attainable water solubility.

The aquatic toxicity of was estimated using the Petrotox computer model, which combines a partitioning model used to calculate the aqueous concentration of hydrocarbon components as a function of substance loading with the Target Lipid Model used to calculate acute and chronic toxicity of non-polar narcotic chemicals. Petrotox computes toxicity based on the summation of the aqueous-phase concentrations of hydrocarbon block(s) that represent a hydrocarbon substance and membrane-water partitioning coefficients (K_MW) that describe the partitioning of the hydrocarbons between the water and organism. Results of computer modelling to estimate chronicity in a 21-day freshwater invertebrate study, based on reproduction, show that this substance will not produce toxicity at or below its maximum attainable water solubility.

The aquatic toxicity of was estimated using the Petrotox computer model, which combines a partitioning model used to calculate the aqueous concentration of hydrocarbon components as a function of substance loading with the Target Lipid Model used to calculate acute and chronic toxicity of non-polar narcotic chemicals. Petrotox computes toxicity based on the summation of the aqueous-phase concentrations of hydrocarbon block(s) that represent a hydrocarbon substance and membrane-water partitioning coefficients (K_MW) that describe the partitioning of the hydrocarbons between the water and organism. Results of computer modelling to estimate chronicity in a 21-day freshwater invertebrate study, based on reproduction, show that this substance will not produce toxicity at or below its maximum attainable water solubility.

The aquatic toxicity of was estimated using the Petrotox computer model, which combines a partitioning model used to calculate the aqueous concentration of hydrocarbon components as a function of substance loading with the Target Lipid Model used to calculate acute and chronic toxicity of non-polar narcotic chemicals. Petrotox computes toxicity based on the summation of the aqueous-phase concentrations of hydrocarbon block(s) that represent a hydrocarbon substance and membrane-water partitioning coefficients (K_MW) that describe the partitioning of the hydrocarbons between the water and organism. Results of computer modelling to estimate chronicity in a 21-day freshwater invertebrate study, based on reproduction, show that this substance will not produce toxicity at or below its maximum attainable water solubility.

The aquatic toxicity of was estimated using the Petrotox computer model, which combines a partitioning model used to calculate the aqueous concentration of hydrocarbon components as a function of substance loading with the Target Lipid Model used to calculate acute and chronic toxicity of non-polar narcotic chemicals. Petrotox computes toxicity based on the summation of the aqueous-phase concentrations of hydrocarbon block(s) that represent a hydrocarbon substance and membrane-water partitioning coefficients (K_MW) that describe the partitioning of the hydrocarbons between the water and organism. Results of computer modelling to estimate chronicity in a 21-day freshwater invertebrate study, based on reproduction, show that this substance will not produce toxicity at or below its maximum attainable water solubility.

The aquatic toxicity of was estimated using the Petrotox computer model, which combines a partitioning model used to calculate the aqueous concentration of hydrocarbon components as a function of substance loading with the Target Lipid Model used to calculate acute and chronic toxicity of non-polar narcotic chemicals. Petrotox computes toxicity based on the summation of the aqueous-phase concentrations of hydrocarbon block(s) that represent a hydrocarbon substance and membrane-water partitioning coefficients (K_MW) that describe the partitioning of the hydrocarbons between the water and organism. Results of computer modelling to estimate chronicity in a 21-day freshwater invertebrate study, based on reproduction, show that this substance will not produce toxicity at or below its maximum attainable water solubility.

The aquatic toxicity of was estimated using the Petrotox computer model, which combines a partitioning model used to calculate the aqueous concentration of hydrocarbon components as a function of substance loading with the Target Lipid Model used to calculate acute and chronic toxicity of non-polar narcotic chemicals. Petrotox computes toxicity based on the summation of the aqueous-phase concentrations of hydrocarbon block(s) that represent a hydrocarbon substance and membrane-water partitioning coefficients (K_MW) that describe the partitioning of the hydrocarbons between the water and organism. Results of computer modelling to estimate chronicity in a 21-day freshwater invertebrate study, based on reproduction, show that this substance will not produce toxicity at or below its maximum attainable water solubility.

The study was performed to evaluate the toxicity of the water accommodated fractions (WAFs) of the test substance Vista C13-C16 to the water fleaCeriodaphnia dubia, in a semi-static system. The test was ended when 60% of the control females had produced 3 broods (6 days).

The water accommodated fractions were prepared by mixing 1 volume of the test substance with 10 volumes of dilution water. The dilution water was reconstituted moderately hard water prepared in the laboratory according to USEPA (USEPA, 1994. Short-term methods for estimating the chronic toxicity of effluents and receiving water to freshwater organisms. EPA/600/4-91/002). A range-finding test with 0, 1, 10 and 100 % WAF allowed setting the high concentration at 100% WAF for the definitive test. The definitive test was performed with 0, 12.5, 25, 50, 75 and 100 % WAF. The stock solution was prepared on alternate days as WAF by mixing 1 volume of test substance to 10 volumes of dilution water. The solution was mixed for 20±1 hours and the WAF was extracted from a point near the bottom of the mixing chamber by siphoning.

10 replicates, each containing one organism, were tested for each treatment. The test media were renewed daily. Mortality and reproduction were assessed daily.

An EL₂₅(reported as IC₂₅in the study report) was calculated for reproduction by linear interpolation:

EL₂₅= 80.9 % WAF

However, the statistical study showed that there was no statistical difference between treatment groups (including control group) for mortality as well as for reproduction. Therefore, the No Observed Effect Loading Rate based on adult mortality and reproduction (expressed as number of young per female) was set at > 100 % WAF.

NOELR = 100% WAF