Arachidonic acid release and prostaglandin synthesis in a macrophage-like cell line exposed to asbestos

Enhanced lipid peroxidation in lung lavage of rats after inhalation of asbestos

Exposure of phagocytic cells to asbestos in vitro results in an augmented production of reactive oxygen metabolites and increased peroxidation of lipids. The aim of this investigation was to assess the extent of lipid peroxidation both in cells and fluid obtained from bronchoalveolar lavage (BAL), and in lungs of rats exposed to crocidolite asbestos or titanium dioxide (TiO2), a nonfibrous particulate control. In comparison to sham and TiO2-exposed rats, the BAL fluid and cells of crocidolite-exposed animals contained significantly elevated levels of malondialdehyde (MDA), a breakdown product of lipid peroxidation detected using high-pressure liquid chromatography (HPLC). In contrast, no significant differences in MDA were detected in lavaged lung tissue from these animals. Inhalation of crocidolite caused an early inflammatory response characterized by elevated numbers of polymorphonuclear leukocytes and lymphocytes, as well as enhanced total protein in BAL. Pulmonary fibrosis and increased lung hydroxyproline also were observed after 20 days of exposure. Exposure to TiO2 did not cause inflammation, pulmonary fibrosis, or elevated amounts of hydroxyproline in the lung. Our results show that exposure to the fibrogenic and inflammatory mineral, crocidolite, results in an enhanced lipid peroxidation in BAL cells and fluid not observed after inhalation of the particulate TiO2. These novel observations suggest that MDA in BAL may be useful as a biomarker of exposure to inhaled asbestos or other oxidants.

Brief inhalation of asbestos compromises superoxide production in cells from bronchoalveolar lavage

Production of superoxide (O-.2) was measured in alveolar macrophages (AM) exposed to asbestos in vitro and in cells obtained from bronchoalveolar lavage (BAL) of rats inhaling asbestos. Steady state levels of O-.2 released by AM in vitro were dose and time dependent in response to crocidolite, chrysotile, and opsonized zymosan, a particulate used to trigger O-.2 generation. In contrast, an inhalation exposure for 1 h to crocidolite or for 6 days to either crocidolite or chrysotile asbestos resulted in a decreased production of O-.2 by BAL cells. Likewise, BAL cells from rats inhaling chrysotile for 1 h or crocidolite for 9 days exhibited a diminished capacity to secrete O-.2 when challenged with the particulate opsonized zymosan. Diminished generation of O-.2 by asbestos occurred in BAL cell populations containing either significantly increased numbers of polymorphonuclear leukocytes and lymphocytes (6- and 9-day exposures) or 99% AM (1-h exposure). Thus, these novel observations suggest that short-term inhalation of asbestos compromises the ability of BAL cells to produce O-.2 in the presence or absence of an additional phagocytic stimulus.

Oxidant production by control and inflammatory bronchoalveolar leukocyte populations treated with mineral dusts in vitro

Using a rat model we set out to determine whether exposure of bronchoalveolar-derived leukocytes to pathogenic mineral dusts in vitro caused them to undergo an oxidative burst and release potentially harmful oxidants. Three different populations, obtained by bronchoalveolar lavage, were chosen: control cells, cells obtained following instillation of heat-killed Corynebacterium parvum into the lung, and cells obtained following instillation of quartz. None of the populations showed any evidence of superoxide anion or hydrogen peroxide production when treated in vitro with the pathogenic dusts quartz and chrysotile asbestos, or the inert particulate titanium dioxide. Zymosan caused modest release of superoxide anion with all three populations, indicating that a respiratory burst was being provoked, while PMA, a soluble inducer of leukocyte oxidative burst, caused large-scale production of both oxidants. Preopsonization of mineral dust in rat serum did not render them capable of provoking an oxidative burst from lung-derived leukocytes.

In vitro correlates of mineral dust toxicity

In vitro studies of mineral fibres have shown that these materials are capable of causing the production of free radical damage (measured by the accumulation of thiobarbituric acid-reactive material) in a way that does not depend on fibre morphology but rather on a surface property, probably the presence of iron. The DNA-damaging activities of the same dusts were measured in an assay based on the production of single-stranded DNA. Activity in this assay was again not dependent on the presence of fibres. In contrast the cytotoxicity of mineral fibres towards V79-4 cells correlated better with in vivo tumorigenicity than did either of the above activities. The activity of fibres against a macrophage-like cell demonstrated that both fibre morphology and chemical properties are important determinants of biological activity.

In vitro biological effects of volcanic ash from Mount Sakurajima

Mount Sakurajima in the south of the Kyushu Island of Japan erupts hundreds of times a year and continuously emits large amounts of ash. More than a million people live under this ash plume, and there is considerable concern about the possible effects of this on their health. We have studied the physicochemical characteristics and in vitro effects of airborne ash collected at 8 km from the crater. More than 30% of the ash was found to be SiO2 (w/w) with most of the particles within the respirable size range. The ash did not inhibit the colony formation of V79-4 cells and failed to activate complement or generate chemotactic factor activity in samples of fresh human serum. It was minimally active in causing the release of lysosomal enzymes from human neutrophile, and did not cause arachidonic acid release from macrophage-like cells. These results were in accord with our epidemiological study, in which very low prevalences of nonspecific respiratory disease were demonstrated even at the area with highest ash exposure.