Rannug U
Environ Health Perspect. 1983 Jan;47:161-9. doi: 10.1289/ehp.8347161.
The mutagenicity of motor vehicle exhausts has been studied by using Salmonella typhimurium strains TA 98 and TA 100. Acetone extracts of the particulate phase and the gas phase have been tested in the presence and absence of a metabolizing system (S9). The particulate phases from medium- and heavy-duty diesel vehicles were tested. The vehicles were driven according to a modified 13 mode test, and the particulate phase was sampled at mode 6 (maximum load and intermediate engine speed) and mode 12 (10% load and rated speed). In mode 6 all vehicles gave approximately the same mutagenicity in strain TA 98 (50,000-90,000 revertants/kW-hr) as well as in TA 100 (200,000-360,000 revertants/kW-hr). A higher mutagenic effect, in some cases up to 10 times, was seen with mode 12.Light-duty vehicles of different year models were tested using different fuel/engine combinations. The vehicles were driven according to FTP 72 or ECE driving cycle. Cold starts at two different temperature levels, approx. 0 degrees C and 23 degrees C, respectively, were also compared. Based on the mutagenicity of the particulate extracts (given as revertants per km), the light-duty vehicles could be divided into three main groups. The first group, the high mutagenicity group, giving 100,000-700,000 revertants/km, consists only of diesel cars. In the medium mutagenicity group, giving between 20,000 and 100,000 revertants/km, different gasoline fuels are placed, i.e., leaded and lead-free gasoline as well as alcohol/gasoline fuels. Two other fuels, methanol (M95) and propane (LPG), constitute the low mutagenicity group, giving less than 20,000 revertants/km. Fuels from the medium effect group will produce a particulate phase with low mutagenicity if the vehicle is equipped with a three way catalyst with closed loop, or fuel injection. The cold start temperature did not change this classification, since all samples gave a somewhat higher mutagenic effect at the low temperature. With the ECE driving cycle, much lower mutagenicity was noted with the diesel cars than in the tests with the FTP-72 driving cycle, at least with tester strain TA 98. On strain TA 100 the diesel exhaust samples still showed a much higher mutagenicity than other samples. Acetone extracts of the gas phase from diesel and gasoline exhaust (trapped in ice/water condensers and CO(2)/ethanol condensers) also gave mutagenic effects. The contribution of the gas phase to the mutagenic effects seems to be more important in the absence of S9 and more important in the case of gasoline exhausts.
利用鼠伤寒沙门氏菌TA 98和TA 100菌株研究了机动车尾气的致突变性。对颗粒相和气相的丙酮提取物在有和没有代谢系统(S9)的情况下进行了测试。测试了中型和重型柴油车的颗粒相。车辆按照改进的13工况试验进行驾驶,并在工况6(最大负荷和中等发动机转速)和工况12(10%负荷和额定转速)下采集颗粒相。在工况6下,所有车辆在TA 98菌株中产生的致突变性大致相同(50,000 - 90,000回复突变体/kW·时),在TA 100菌株中也是如此(200,000 - 360,000回复突变体/kW·时)。在工况12下观察到更高的致突变效应,在某些情况下高达10倍。使用不同燃料/发动机组合对不同年份车型的轻型车辆进行了测试。车辆按照FTP 72或ECE驾驶循环进行驾驶。还比较了分别在约0摄氏度和23摄氏度两个不同温度水平下的冷启动情况。根据颗粒提取物的致突变性(以每公里回复突变体表示),轻型车辆可分为三个主要组。第一组,高致突变性组,每公里产生100,000 - 700,000回复突变体,仅由柴油车组成。在中等致突变性组中,每公里产生20,000至100,000回复突变体,包含不同的汽油燃料,即含铅和无铅汽油以及酒精/汽油燃料。另外两种燃料,甲醇(M95)和丙烷(LPG),构成低致突变性组,每公里产生少于20,000回复突变体。如果车辆配备闭环三元催化剂或燃油喷射装置,中等效应组的燃料将产生低致突变性的颗粒相。冷启动温度并未改变这种分类,因为所有样品在低温下都表现出略高的致突变效应。采用ECE驾驶循环时,柴油车的致突变性比采用FTP - 72驾驶循环的测试中低得多,至少在测试菌株TA 98中是这样。在TA 100菌株上,柴油尾气样品的致突变性仍比其他样品高得多。柴油和汽油尾气气相的丙酮提取物(捕获在冰/水冷凝器和CO₂/乙醇冷凝器中)也产生了致突变效应。在没有S9的情况下,气相对致突变效应的贡献似乎更重要,并且在汽油尾气的情况下更重要。