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Genotoxicity, cytotoxicity, and reactive oxygen species induced by single-walled carbon nanotubes and C(60) fullerenes in the FE1-Mutatrade markMouse lung epithelial cells
Authors:Jacobsen Nicklas Raun  Pojana Giulio  White Paul  Møller Peter  Cohn Corey Alexander  Korsholm Karen Smith  Vogel Ulla  Marcomini Antonio  Loft Steffen  Wallin Håkan
Affiliation:1. National Research Center for the Working Environment, DK‐2100 Copenhagen ?, Denmark;2. Department of Environmental Sciences, University Ca'Foscari of Venice, 30123 Venice, Italy;3. Mutagenesis Section, Safe Environments Program, Healthy Environments and Consumer Safety Branch, Health Canada, Ottawa, Canada;4. Department of Environmental Health, University of Copenhagen, 1014 Copenhagen K, Denmark;5. Department of Infectious Disease Immunology, Statens Serum Institut, DK‐2300 Copenhagen S, Denmark
Abstract:Viability, cell cycle effects, genotoxicity, reactive oxygen species production, and mutagenicity of C(60) fullerenes (C(60)) and single-walled carbon nanotubes (SWCNT) were assessed in the FE1-Mutatrade markMouse lung epithelial cell line. None of these particles induced cell death within 24 hr at doses between 0 and 200 microg/ml or during long-term subculture exposure (576 hr) at 100 microg/ml, as determined by two different assays. However, cell proliferation was slower with SWCNT exposure and a larger fraction of the cells were in the G1 phase. Exposure to carbon black resulted in the greatest reactive oxygen species generation followed by SWCNT and C(60) in both cellular and cell-free particle suspensions. C(60) and SWCNT did not increase the level of strand breaks, but significantly increased the level of FPG sensitive sites/oxidized purines (22 and 56%, respectively) determined by the comet assay. The mutant frequency in the cII gene was unaffected by 576 hr of exposure to either 100 microg/ml C(60) or SWCNT when compared with control incubations, whereas we have previously reported that carbon black and diesel exhaust particles induce mutations using an identical exposure scenario. These results indicate that SWCNT and C(60) are less genotoxic in vitro than carbon black and diesel exhaust particles.
Keywords:comet assay  FE1‐MML  in vitro  mutation  oxidative damage
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