Oxidative damage to plasmid DNA induced by airborne PM10 (particulate matter with an aerodynamic diameter of 10 μm or less) is caused by the bioavailable (i.e., soluble) heavy metals on the particle surface. Howe...Oxidative damage to plasmid DNA induced by airborne PM10 (particulate matter with an aerodynamic diameter of 10 μm or less) is caused by the bioavailable (i.e., soluble) heavy metals on the particle surface. However, quantitative analyses of the links between PM10 and oxidative damage are limited. In this study, plasmid DNA assay and ICP-MS were applied to study oxidative capacity and trace element compositions, respectively, of summer and winter PM10 samples collected at several sites (Sun Yat Sen Municipal Park (SYSP) and Av. de Horta e Costa (AHC) on the Macao peninsula and Macao University on Tai- pa Island (TI)) in Macao. At AHC and TI, the oxidative capacity of PM10 collected in winter was higher than that collected in summer, for both the whole sample and the water-soluble fraction. In contrast, no seasonal variation was noted at SYSP. PMI0 exhibited the highest oxidative capacity at SYSP and lowest oxidative capacity at TI in both seasons, demonstrating that the PMl0 collected on the Macao peninsula had a higher toxicity than that from Taipa Island. ICP-MS analyses revealed that the concentrations of total analyzed trace elements and their water-soluble components in PMI0 from TI and AHC were higher in winter than in summer, whereas SYSP displayed the opposite trend. The extents of oxidative damage induced by the wa- ter-soluble fractions and intact whole particles were generally similar, implying that the oxidative damage caused by particles in Macao resulted mainly from the water-soluble fraction. The oxidative capacities of PM10 were positively correlated with both whole and soluble Zn at the 95% confidence level, indicating that Zn was the major element responsible for the oxidative damage caused by particles in Macao. Other heavy metals, such as Cr, Cu, Cd, Ni, As, and Pb, also exhibited elevated concen- trations, and the potential health impacts of these metals should be considered.展开更多
基金supported by the National Natural Science Foundation of China (Grant No. 41030213)the Macao Foundation for Development of Science and Technology (Grant No. 023/2006/A)
文摘Oxidative damage to plasmid DNA induced by airborne PM10 (particulate matter with an aerodynamic diameter of 10 μm or less) is caused by the bioavailable (i.e., soluble) heavy metals on the particle surface. However, quantitative analyses of the links between PM10 and oxidative damage are limited. In this study, plasmid DNA assay and ICP-MS were applied to study oxidative capacity and trace element compositions, respectively, of summer and winter PM10 samples collected at several sites (Sun Yat Sen Municipal Park (SYSP) and Av. de Horta e Costa (AHC) on the Macao peninsula and Macao University on Tai- pa Island (TI)) in Macao. At AHC and TI, the oxidative capacity of PM10 collected in winter was higher than that collected in summer, for both the whole sample and the water-soluble fraction. In contrast, no seasonal variation was noted at SYSP. PMI0 exhibited the highest oxidative capacity at SYSP and lowest oxidative capacity at TI in both seasons, demonstrating that the PMl0 collected on the Macao peninsula had a higher toxicity than that from Taipa Island. ICP-MS analyses revealed that the concentrations of total analyzed trace elements and their water-soluble components in PMI0 from TI and AHC were higher in winter than in summer, whereas SYSP displayed the opposite trend. The extents of oxidative damage induced by the wa- ter-soluble fractions and intact whole particles were generally similar, implying that the oxidative damage caused by particles in Macao resulted mainly from the water-soluble fraction. The oxidative capacities of PM10 were positively correlated with both whole and soluble Zn at the 95% confidence level, indicating that Zn was the major element responsible for the oxidative damage caused by particles in Macao. Other heavy metals, such as Cr, Cu, Cd, Ni, As, and Pb, also exhibited elevated concen- trations, and the potential health impacts of these metals should be considered.
