Hard metals (WC-Co) are made of a mixture of cobalt metal (Co, 5-10%) and tungsten carbide particles (WC, >80%). Excessive inhalation of WC-Co is associated with the occurrence of different lung diseases including an excess of lung cancers. The elective toxicity of hard metal is based on a physico-chemical interaction between cobalt metal and tungsten carbide particles to produce activated oxygen species. The aim of the present study was to assess the genotoxic activity of hard metal particles as compared with Co and WC alone. In human peripheral lymphocytes incubated with Co or WC-Co, a dose- and time-dependent increased production of DNA single strand breaks (ssb) was evidenced by alkaline single cell gel electrophoresis (SCGE) and modified alkaline elution (AE) assays. Addition of 1 M formate, a hydroxyl radical scavenger, had a protective effect against the production of ssb by both WC-Co or Co alone. On the basis of an equivalent cobalt-content, WC-Co produced significantly more ssb than Co. WC alone did not produce DNA ssb detectable by the AE assay, but results obtained with the SCGE assay may suggest that it either allows some uncoiling of the chromatin loops or induces the formation of slowly migrating fragments. Overall, this in vitro study is the first demonstration of the clastogenic property of cobalt metal-containing dusts. The results are consistent with the implication of an increased production of hydroxyl radicals when Co is mixed with WC particles. The SCGE results also suggest that WC may modify the structure of the chromatin, leading to an increased DNA sensitivity to clastogenic effects. Both mechanisms are not mutually exclusive and may concurrently contribute to the greater clastogenic activity of WC-Co dust. This property of WC-Co particles may account for the excess of lung cancers observed in hard metal workers.
The aim of this study is to assess the ability of three methods, alkaline elution (AE), nick translation (NT), and single-cell gel electrophoresis (SCGE), to detect DNA single-strand breaks (ssb) in human peripheral blood lymphocytes (HPBL) exposed in vitro to three genotoxic agents; gamma-rays, ethyl methanesulfonate (EMS) and benzo[a]pyrene diol epoxide (BPDE). The ultimate objective is to select the most feasible, sensitive, and reproducible method for the monitoring of populations exposed to genotoxic agents. AE and NT do not seem suitable assays. AE is able to detect DNA lesions induced by the three compounds, but only at relatively high doses (2 Gy, 5 mM EMS and 20 microM BPDE). With NT, DNA alterations induced by gamma-rays are not detected and ssb are only evidenced after exposure to EMS (80 mM), which already alters the viability of the lymphocytes. Nick translation is able to detect ssb induced by 10 microM BPDE. Compared to the other assays, the sensitivity of the SCGE assay is significantly higher since statistically significant changes were detected after incubation with 0.5 mM EMS and 1.25 microM BDPE. SCGE is a relatively simple method, not time-consuming and applicable to a large number of samples per working day. In conclusion, on the basis of the results of this in vitro comparison, SCGE seems a promising method for the monitoring of populations exposed to genotoxic chemicals.
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