juillet 2023 — Long-term exposure to airborne metals and risk of cancer in the French cohort Gazel. Environment International vol. 177, , p. 107999
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juin 2023 — Les teneurs en platinoïdes dans les mousses terrestres. Les cahiers de la Recherche : Santé, Environnement, Travail , n° 21, p. 23-25
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2022 — Modeling exposure to airborne metals using moss biomonitoring in cemeteries in two urban areas around Paris and Lyon in France. Environmental Pollution vol. 303, , chap. 119097
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novembre 2021 — Inventory of corticolous lichens in three Parisian sites and in the arboretum of Chèvreloup (Yvelines). Naturae , n° 23, p. 321-332
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2021 — Inventaire des lichens corticoles dans trois sites parisiens et dans l’arboretum de Chèvreloup (Yvelines). Naturae vol. 23, , p. 321-332
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2021 — Are Grimmia mosses good biomonitors for urban atmospheric metallic pollution? Preliminary evidence from a French case study on cadmium. Atmosphere vol. 12, , p. 491
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avril 2020 — Métaux, pollution de l’air et santé : Les mousses, des alliées originales en épidémiologie. Médecine/Sciences vol. 36, n° 4, p. 376-381
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2019 — Long-term exposure to atmospheric metals assessed by mosses and mortality in France. Environment International vol. 129, , p. 145-153
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2018 — The coastal environment affects lead and sodium uptake by the moss Hypnum cupressiforme used as an air pollution biomonitor. Chemosphere vol. 193, , 506-513.
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2016 — Air pollution below WHO levels decreases by 40 % the links of terrestrial microbial networks. Environmental Chemistry Letters vol. 14, n° 4, p. 467-475
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2015 — Characterisation and distribution of deposited trace elements transported over long and intermediate distances in north-eastern France using Sphagnum peatlands as a sentinel ecosystem. Atmospheric Environment vol. 101, , p. 286-293
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2013 — To What Extent Do Food Preferences Explain the Trophic Position of Heterotrophic and Mixotrophic Microbial Consumers in a Sphagnum Peatland?. Microbial Ecology vol. 66, n° 3, p. 571-580
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2013 — Using testate amoeba as potential biointegrators of atmospheric deposition of phenanthrene (polycyclic aromatic hydrocarbon) on “moss/soil interface-testate amoeba community” microecosystems. Ecotoxicology vol. 22, n° 2, p. 287-294
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2012 — Using “bryophytes and their associated testate amoeba” microsystems as indicators of atmospheric pollution. Ecological Indicators vol. 13, n° 1, p. 144-151
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2010 — Relationship of Atmospheric Pollution Characterized by Gas (NO2) and Particles (PM10) to Microbial Communities Living in Bryophytes at Three Differently Polluted Sites (Rural, Urban, and Industrial). Microbial Ecology vol. 59, n° 2, p. 324-334
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2010 — Accumulation Capacities of Particulate Matter in an Acrocarpous and a Pleurocarpous Moss Exposed at Three Differently Polluted Sites (Industrial, Urban and Rural). Water, Air, & Soil Pollution vol. 212, 1-4, p. 205-217
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2010 — Effects of urban particulate deposition on microbial communities living in bryophytes: An experimental study. Ecotoxicology and Environmental Safety vol. 73, n° 7, p. 1776-1784
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2007 — Responses of Arvicola terrestris scherman populations to agricultural practices, and to Talpa europaea abundance in eastern France. Agriculture, Ecosystems & Environment vol. 122, n° 3, p. 392-398
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