Inhalation of two putative Gulf War toxins by mice.

We employed our inhalation methodology to examine whether biomarkers of inflammation and oxidative stress would be produced in mice following inhalation of aerosols containing carbonaceous particles or the vapor of pesticides prevalent during the first Gulf War. Exposure to two putative Gulf War Illness toxins, fine airborne particles and the pesticide malathion, increased biomarkers of inflammation and oxidative stress in Friend virus B (FVB) female mice. Mice inhaling particles 24 h before had increased lung lavage and plasma Leukotriene B4 (LTB4) (a biomarker of inflammation) and PGF2α (a biomarker of oxidative stress) levels, lung lavage protein and lung lavage lactic dehydrogenase (LDH) levels. These changes were a function of particle density and exposure time. Compared to particle inhalation, mice inhaling malathion 24 h before had small increase in plasma LTB4 and PGF2α levels but no increase in lung lavage LTB4, lung lavage protein, lung lavage LDH, and lung lavage alveolar macrophage (AM) levels compared to unexposed control mice. AM from particle-exposed mice contained phagocytosed particles, while AM from malathion-exposed mice showed no abnormalities. Our results indicate that inhaling particles or malathion can alter inflammatory and oxidative biomarkers in mice and raise the possibility that these toxins may have altered inflammation and oxidative stress biomarkers in Gulf War-exposed individuals.

Effects of fine carbonaceous particles containing high and low unpaired electron spin densities on lungs of female mice.

The negative impacts on human health that accompany inhalation of atmospheric particles are documented in numerous epidemiologic studies, but the effect of specific chemical properties of the particles is generally unknown. We developed and employed technology for generating inhalable aerosols of carbonaceous air pollution particles that have specific physical and chemical properties. We find that inhaling particles with greater unpaired electron spin (free radical) densities stimulates greater lung inflammatory and oxidative stress responses. Cultured alveolar macrophages take up more particles of greater free radical content, develop mitochondrial abnormalities, and release more leukotriene B(4) (LTB(4)) than alveolar macrophages exposed to lesser free-radical-containing particles in vitro. Mice exposed to high free radical particles in vivo also develop mitochondrial abnormalities in alveolar macrophages and increased oxidative stress, which is reflected by increases in lung nitrotyrosine staining and lung lavage nitrogen oxide levels compared with those of lesser free radical density. These results provide insight for the unexplained geographic differences and have implications for fossil fuel combustion conditions and the impact of fine particles on health and disease.