Reactive oxygen species activity and chemical speciation of size-fractionated atmospheric particulate matter from Lahore, Pakistan: an important role for transition metals.

In this study a sensitive macrophage-based in vitro reactive oxygen species (ROS) assay was coupled with chemical fractionation tools and a year-long sampling program to further our understanding of the role of water-soluble metals in aerosol toxicity. The location is the polluted urban environment of Lahore, Pakistan, where we collected 24 h PM10 and PM2.5 samples every 6(th) day from January 2007 through January 2008. The intrinsic (i.e. particulate matter (PM) mass-normalized) toxicity of the Lahore aerosol, representative of highly polluted developing nations, is compared with toxicity of aerosols from several urban environments in the USA. The monthly patterns of PM2.5 and PM10 water-soluble aerosol ROS-activity were similar with maxima in fall and mid-late winter, and minima over the period April through August and in early winter. Coarse PM ROS-activity was a consistent and significant component (42 +/- 13%) of total activity. The intrinsic activity of the PM2.5 and coarse PM was remarkably similar in a given month. Chelex treatment of the Lahore PM extracts removed a very large and consistent fraction of the water-soluble ROS-activity (96.5 +/- 2.8% for the PM10). Desferrioxamine (DFO) treatment of these extracts also removed a large and relatively consistent fraction of the water-soluble ROS-activity (87.8 +/- 5.3%). Taken together, the DFO and Chelex data imply that transition metals, particularly iron, are major factors mediating ROS-activity of water extracts of the Lahore PM. Statistical modeling (step-wise linear regression and cluster analysis) identified a small subset of metals (Mn, Co, Fe, Ni) as the potential ROS-active species. Several water-soluble "trace" metals present at very high concentrations in the PM extracts (Zn, Pb, Cd), that were effectively removed on Chelex, but are not redox-active, exhibited relatively poor correlations with ROS. The median intrinsic water-soluble ROS-activity measured in the Lahore PM was more than an order-of-magnitude greater than that measured in aerosols from the Long Beach/Los Angeles region and approximately 4-fold greater than the activity of Denver area PM.

Toxic metals in the atmosphere in Lahore, Pakistan.

Aerosol mass (PM(10) and PM(2.5)) and detailed elemental composition were measured in monthly composites during the calendar year of 2007 at a site in Lahore, Pakistan. Elemental analysis revealed extremely high concentrations of Pb (4.4microg m(-3)), Zn (12microg m(-3)), Cd (0.077microg m(-3)), and several other toxic metals. A significant fraction of the concentration of Pb (84%), Zn (98%), and Cd (90%) was contained in the fine particulate fraction (PM(2.5) and smaller); in addition, Zn and Cd were largely (>or=60%) water soluble. The 2007 annual average PM(10) mass concentration was 340microg m(-3), which is well above the WHO guideline of 20microg m(-3). Dust sources were found to contribute on average (maximum) 41% (70%) of PM(10) mass and 14% (29%) of PM(2.5) mass on a monthly basis. Seasonally, concentrations were found to be lowest during the monsoon season (July-September). Principle component analysis identified seven factors, which combined explained 91% of the variance of the measured components of PM(10). These factors included three industrial sources, re-suspended soil, mobile sources, and two regional secondary aerosol sources likely from coal and/or biomass burning. The majority of the Pb was found to be associated with one industrial source, along with a number of other toxic metals including As and Cr. Cadmium, another toxic metal, was found at concentrations 16 times higher than the maximum exposure level recommended by the World Health Organization, and was concentrated in one industrial source that was also associated with Zn. These results highlight the importance of focusing control strategies not only on reducing PM mass concentration, but also on the reduction of toxic components of the PM as well, to most effectively protect human health and the environment.