. . "6"^^ . "Toxicology Letters" . "Pechout, Martin" . "0378-4274" . . . "1" . "Genotoxic potential of organic extracts from particle emissions of diesel and rapeseed oil powered engines."@en . . . "RIV/46747885:24210/12:#0003020!RIV13-GA0-24210___" . "7"^^ . . "137984" . . . . "3"^^ . "Genotoxic potential of organic extracts from particle emissions of diesel and rapeseed oil powered engines."@en . "Schmuczerov\u00E1, Jana" . . "Milcov\u00E1, Alena" . "000306887000002" . "The present study was performed to identify possible genotoxicity induced by organic extracts from particulate matter in the exhaust of Cummins ISBe4 and Zetor 1505 diesel engines run on diesel fuel, biodiesel and neat heated fuel-grade rapeseed oil. Diluted exhaust was sampled with high-volume samplers on Teflon coated filters. Filters were extracted with dichlormethane (DCM) and DNA adduct levels induced by extractable organic matter (EOM) in an acellular assay of calf thymus DNA coupled with P-32-postlabeling in the presence and absence of rat liver microsomal S9 fraction were employed. Simultaneously, the chemical analysis of 12 priority PAHs in EOM, including 7 carcinogenic PAHs (c-PAHs) was performed. The results suggest that diesel emissions contain substantially more total PAHs than rapeseed oil emissions (for the ESC) or that these concentrations were comparable (for the WHSC and NRSC), while c-PAHs levels were comparable (for the ESC) or significantly higher (for the WHSC and NRSC) for rapeseed oil emissions. DNA adduct levels induced by diesel and rapeseed oil derived EOM were comparable, but consistently slightly higher for diesel than for rapeseed oil. Highly significant correlations were found between 12 priority PAHs concentrations and DNA adduct levels (0.980; p < 0.001) and these correlations were even stronger for c-PAHs (0.990; p < 0.001). Metabolic activation by the microsomal S9 fraction resulted in several fold higher genotoxicity, suggesting a major contribution of PAHs to genotoxicity. Directly acting compounds, other than c-PAHs, and not requiring S9 to exhibit DNA reactivity were also significant. Generally. DNA adduct levels were more dependent on the type of engine and the test cycle than on the fuel. Our findings suggest that the genotoxicity of particulate emissions from the combustion of rapeseed oil is significant and is comparable to that from the combustion of diesel fuel."@en . . "Genotoxic potential of organic extracts from particle emissions of diesel and rapeseed oil powered engines." . "Topinka, Jan" . "Genotoxic potential of organic extracts from particle emissions of diesel and rapeseed oil powered engines." . . "Vojt\u00ED\u0161ek, Michal" . "Maza\u010D, Martin" . . "US - Spojen\u00E9 st\u00E1ty americk\u00E9" . "The present study was performed to identify possible genotoxicity induced by organic extracts from particulate matter in the exhaust of Cummins ISBe4 and Zetor 1505 diesel engines run on diesel fuel, biodiesel and neat heated fuel-grade rapeseed oil. Diluted exhaust was sampled with high-volume samplers on Teflon coated filters. Filters were extracted with dichlormethane (DCM) and DNA adduct levels induced by extractable organic matter (EOM) in an acellular assay of calf thymus DNA coupled with P-32-postlabeling in the presence and absence of rat liver microsomal S9 fraction were employed. Simultaneously, the chemical analysis of 12 priority PAHs in EOM, including 7 carcinogenic PAHs (c-PAHs) was performed. The results suggest that diesel emissions contain substantially more total PAHs than rapeseed oil emissions (for the ESC) or that these concentrations were comparable (for the WHSC and NRSC), while c-PAHs levels were comparable (for the ESC) or significantly higher (for the WHSC and NRSC) for rapeseed oil emissions. DNA adduct levels induced by diesel and rapeseed oil derived EOM were comparable, but consistently slightly higher for diesel than for rapeseed oil. Highly significant correlations were found between 12 priority PAHs concentrations and DNA adduct levels (0.980; p < 0.001) and these correlations were even stronger for c-PAHs (0.990; p < 0.001). Metabolic activation by the microsomal S9 fraction resulted in several fold higher genotoxicity, suggesting a major contribution of PAHs to genotoxicity. Directly acting compounds, other than c-PAHs, and not requiring S9 to exhibit DNA reactivity were also significant. Generally. DNA adduct levels were more dependent on the type of engine and the test cycle than on the fuel. Our findings suggest that the genotoxicity of particulate emissions from the combustion of rapeseed oil is significant and is comparable to that from the combustion of diesel fuel." . . . "diesel engine; toxicity; exhaust; biofuels; biodiesel; rapeseed oil; particulate matter; genotoxicity"@en . . . . "RIV/46747885:24210/12:#0003020" . . . . . . . "10.1016/j.toxlet.2012.04.017" . . "24210" . . "I, P(GA101/08/1717), P(GAP503/11/0142), P(GBP503/12/G147), Z(AV0Z50390703)" . "[2C9B4BD1D0CE]" . . "212" .