Your search keyword '"Elodie Bernard"' showing total 2 results

1. Toxicological Assessment of ITER-Like Tungsten Nanoparticles Using an In Vitro 3D Human Airway Epithelium Model

Author

Isabelle George, Chiara Uboldi, Elodie Bernard, Marcos Sanles Sobrido, Sarah Dine, Agnès Hagège, Dominique Vrel, Nathalie Herlin, Jerome Rose, Thierry Orsière, Christian Grisolia, Bernard Rousseau, and Véronique Malard

Subjects

nanoparticles, tungsten, lung, mucilair™, acute toxicity, Chemistry, QD1-999

Abstract

The International Thermonuclear Experimental Reactor (ITER) is an international project aimed at the production of carbon-free energy through the use of thermonuclear fusion. During ITER operation, in case of a loss-of-vacuum-accident, tungsten nanoparticles (W-NPs) could potentially be released into the environment and induce occupational exposure via inhalation. W-NPs toxicity was evaluated on MucilAir™, a 3D in vitro cell model of the human airway epithelium. MucilAir™ was exposed for 24 h to metallic ITER-like milled W-NPs, tungstate (WO42−) and tungsten carbide cobalt particles alloy (WC-Co). Cytotoxicity and its reversibility were assessed using a kinetic mode up to 28 days after exposure. Epithelial tightness, metabolic activity and interleukin-8 release were also evaluated. Electron microscopy was performed to determine any morphological modification, while mass spectrometry allowed the quantification of W-NPs internalization and of W transfer through the MucilAir™. Our results underlined a decrease in barrier integrity, no effect on metabolic activity or cell viability and a transient increase in IL-8 secretion after exposure to ITER-like milled W-NPs. These effects were associated with W-transfer through the epithelium, but not with intracellular accumulation. We have shown that, under our experimental conditions, ITER-like milled W-NPs have a minor impact on the MucilAir™ in vitro model.

Published

2019

2. In Vitro Analysis of the Effects of ITER-Like Tungsten Nanoparticles: Cytotoxicity and Epigenotoxicity in BEAS-2B Cells

Author

Chiara Uboldi, Marcos Sanles Sobrido, Elodie Bernard, Virginie Tassistro, Nathalie Herlin-Boime, Dominique Vrel, Sébastien Garcia-Argote, Stéphane Roche, Fréderique Magdinier, Gheorghe Dinescu, Véronique Malard, Laurence Lebaron-Jacobs, Jerome Rose, Bernard Rousseau, Philippe Delaporte, Christian Grisolia, and Thierry Orsière

Subjects

tungsten, nanoparticles, tritiated particles, in vitro testing, cytotoxicity, micronuclei formation, DNA damage, epigenetics, DNA methylation, BEAS-2B cells., Chemistry, QD1-999

Abstract

Tungsten was chosen as a wall component to interact with the plasma generated by the International Thermonuclear Experimental fusion Reactor (ITER). Nevertheless, during plasma operation tritiated tungsten nanoparticles (W-NPs) will be formed and potentially released into the environment following a Loss-Of-Vacuum-Accident, causing occupational or accidental exposure. We therefore investigated, in the bronchial human-derived BEAS-2B cell line, the cytotoxic and epigenotoxic effects of two types of ITER-like W-NPs (plasma sputtering or laser ablation), in their pristine, hydrogenated, and tritiated forms. Long exposures (24 h) induced significant cytotoxicity, especially for the hydrogenated ones. Plasma W-NPs impaired cytostasis more severely than the laser ones and both types and forms of W-NPs induced significant micronuclei formation, as shown by cytokinesis-block micronucleus assay. Single DNA strand breaks, potentially triggered by oxidative stress, occurred upon exposure to W-NPs and independently of their form, as observed by alkaline comet assay. After 24 h it was shown that more than 50% of W was dissolved via oxidative dissolution. Overall, our results indicate that W-NPs can affect the in vitro viability of BEAS-2B cells and induce epigenotoxic alterations. We could not observe significant differences between plasma and laser W-NPs so their toxicity might not be triggered by the synthesis method.

Published

2019