Impact of exposure to wood dust on genotoxicity and cytotoxicity in exfoliated buccal and nasal cells.

Wood dust was classified by the IARC as a human carcinogen which causes sinonasal tumours. However, the exposure in different industries varies strongly and the risks of workers depend on the specific situation which can be assessed by the use of biomonitoring methods. The aim of this study was to investigate the workers who are exposed to low dust levels (below the permitted concentrations) with cytogenetic and biochemical methods. Micronuclei (MNi) which are indicative for genomic damage, nuclear buds which reflect gene amplification, binucleated cells which are caused by mitotic disturbances and acute cytotoxicity parameters (pyknosis, karyorrhexis, condensed chromatin, karyolysis) were monitored in buccal and nasal cells of workers of a veneer factory (n = 51) who are exposed to volatile wood-derived compounds, in carpenters of a furniture factory which use no synthetic chemicals (n=38) and in a control group (n = 65). Additionally, markers were measured in blood plasma which reflect inflammations (C-reactive protein, CRP) and the redox status, namely malondialdehyde (MDA) and oxidised low density proteins (oxLDL). No induction of micronucleated cells was observed in both epithelia in the two exposure groups while all other nuclear anomalies except pyknosis were increased; also one health-related biochemical marker (MDA) was significantly elevated in the workers. Taken together, the results of our study show that exposure to low levels of wood dust does not cause formation of MNi indicating that the cancer risks of the workers are not increased as a consequence of genetic damage while positive results were obtained in earlier studies with workers who are exposed to high dust levels. However, our findings indicate that wood dust causes cytotoxic effects which may lead to inflammations.

The sensitivity of biomarkers for genotoxicity and acute cytotoxicity in nasal and buccal cells of welders.

Welders are inhalatively exposed to fumes which contain genotoxic carcinogens and it was found in epidemiological studies that they have increased cancer rates which may be causally related to DNA damage. In order to assess their health risks and to find out which chemicals cause the adverse effects, bioassays can be performed which enable the detection of genetic damage. The aim of the present study was a comparative investigation with exfoliated buccal and nasal cells in regard to induction of chromosomal alterations and acute cytotoxicity in welders and unexposed controls (n=22 per group). To elucidate the factors which account for genotoxic and cytotoxic effects, additional biochemical parameters were monitored reflecting the redox status as well as concentrations of different metals and 1-hydroxypyrene (1-OHP) in body fluids. We found in the nasal cells significant induction of alterations which are indicative for DNA damage, i.e. of micronuclei (MNi) and nuclear buds, while elevated rates of nuclear anomalies reflecting cytotoxic effects (condensed chromatin, karyorrhexis, karyolylsis) were detected in cells from both organs. The levels of certain metals (Cr, Cu, Mn, Mo, Ni), but not markers of oxidative damage were significantly higher in the body fluids of the welders. Multivariate Poisson regression analyses indicate that exposure to Mo (15% MNi increase by one standard deviation increase of Mo in serum), Ni (9% increase) and Mn (14% increase) are positively associated with the induction of MNi in nasal cells while Ni was associated with cytotoxic effects in both types of cells (12 and 16% increase). Taken together, our findings indicate that epithelial cells from the respiratory tract are suitable for the detection of DNA-damaging and cytotoxic effects in welders and can be used to assess health risks associated with genomic instability.