Long-Term Trends for Blue Mussels from the German Environmental Specimen Bank Show First Evidence of Munition Contaminants Uptake
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[1] D. Pröfrock,et al. Release of Ammunition-Related Compounds from a Dutch Marine Dump Site , 2023, Toxics.
[2] M. Brenner,et al. Warship wrecks and their munitions cargo as a threat to the marine environment and humans: The V 1302 "JOHN MAHN" from World War II. , 2022, The Science of the total environment.
[3] J. Koschorreck,et al. Environmental specimen banks and the European Green Deal. , 2022, The Science of the total environment.
[4] J. Koschorreck,et al. 30 years trends of microplastic pollution: Mass-quantitative analysis of archived mussel samples from the North and Baltic Seas. , 2022, The Science of the total environment.
[5] C. D. de Wit,et al. Identifying emerging environmental concerns from long-chain chlorinated paraffins towards German ecosystems. , 2021, Journal of hazardous materials.
[6] E. Achterberg,et al. Explosives compounds from sea-dumped relic munitions accumulate in marine biota. , 2021, The Science of the total environment.
[7] R. D. George,et al. Environmental Characterization of Underwater Munitions Constituents at a Former Military Training Range , 2021, Environmental toxicology and chemistry.
[8] E. Maser,et al. Can seafood from marine sites of dumped World War relicts be eaten? , 2021, Archives of Toxicology.
[9] E. Maser,et al. A Toolbox for the Determination of Nitroaromatic Explosives in Marine Water, Sediment, and Biota Samples on Femtogram Levels by GC-MS/MS , 2021, Toxics.
[10] U. Bickmeyer,et al. Exposure to dissolved TNT causes multilevel biological effects in Baltic mussels (Mytilus spp.). , 2021, Marine environmental research.
[11] M. Brenner,et al. The explosive trinitrotoluene (TNT) induces gene expression of carbonyl reductase in the blue mussel (Mytilus spp.): a new promising biomarker for sea dumped war relicts? , 2020, Archives of Toxicology.
[12] J. Greinert,et al. Exploration of the munition dumpsite Kolberger Heide in Kiel Bay, Germany: Example for a standardised hydroacoustic and optic monitoring approach , 2020 .
[13] E. Maser,et al. Marine bivalves as bioindicators for environmental pollutants with focus on dumped munitions in the sea: A review. , 2020, Marine environmental research.
[14] E. Maser,et al. “Don’t Blast”: blast-in-place (BiP) operations of dumped World War munitions in the oceans significantly increase hazards to the environment and the human seafood consumer , 2020, Archives of Toxicology.
[15] N. Goldenstein,et al. First evidence of explosives and their degradation products in dab (Limanda limanda L.) from a munition dumpsite in the Baltic Sea. , 2020, Marine pollution bulletin.
[16] J. Koschorreck,et al. Seasonal variability in metal and metalloid burdens of mussels: using data from the German Environmental Specimen Bank to evaluate implications for long-term mussel monitoring programs , 2020, Environmental Sciences Europe.
[17] J. Michalak. IDENTIFICATION OF HAZARDS CAUSED BY CHEMICAL MUNITIONS DUMPED IN THE BALTIC SEA , 2020 .
[18] J. Greinert. Practical Guide for Environmental Monitoring of Conventional Munitions in the Seas - Results from the BMBF funded project UDEMM “Umweltmonitoring für die Delaboration von Munition im Meer” Version 1.1 , 2019 .
[19] N. Goldenstein,et al. Nitroaromatic compounds damage the DNA of zebrafish embryos (Danio rerio). , 2019, Aquatic toxicology.
[20] R. D. George,et al. Release of Munitions Constituents in Aquatic Environments Under Realistic Scenarios and Validation of Polar Organic Chemical Integrative Samplers for Monitoring , 2019, Environmental toxicology and chemistry.
[21] P. Esseiva,et al. Monitoring of explosive residues in lake-bottom water using Polar Organic Chemical Integrative Sampler (POCIS) and chemcatcher: determination of transfer kinetics through Polyethersulfone (PES) membrane is crucial. , 2019, Environmental pollution.
[22] E. Achterberg,et al. In Situ Measurements of Explosive Compound Dissolution Fluxes from Exposed Munition Material in the Baltic Sea. , 2019, Environmental science & technology.
[23] E. Maser,et al. Bioaccumulation of 2,4,6-trinitrotoluene (TNT) and its metabolites leaking from corroded munition in transplanted blue mussels (M. edulis). , 2018, Marine pollution bulletin.
[24] J. Koschorreck,et al. Assessment of seafood contamination under the marine strategy framework directive: contributions of the German environmental specimen bank , 2018, Environmental Science and Pollution Research.
[25] R. D. George,et al. Field validation of POCIS for monitoring at underwater munitions sites , 2018, Environmental toxicology and chemistry.
[26] E. Achterberg,et al. Spread, Behavior, and Ecosystem Consequences of Conventional Munitions Compounds in Coastal Marine Waters , 2018, Front. Mar. Sci..
[27] R. D. George,et al. Investigation of polar organic chemical integrative sampler (POCIS) flow rate dependence for munition constituents in underwater environments , 2018, Environmental Monitoring and Assessment.
[28] Eric J Glisch,et al. Review and Synthesis of Evidence Regarding Environmental Risks Posed by Munitions Constituents (MC) in Aquatic Systems , 2017 .
[29] E. Maser,et al. Biomonitoring of 2,4,6-trinitrotoluene and degradation products in the marine environment with transplanted blue mussels (M. edulis). , 2017, Toxicology.
[30] Wojciech Jurczak,et al. Corrosion of ammunition dumped in the Baltic Sea , 2017 .
[31] S. Tanabe,et al. Edward D. Goldberg's proposal of "the Mussel Watch": Reflections after 40years. , 2016, Marine pollution bulletin.
[32] Taylor Chock,et al. Munitions integrity and corrosion features observed during the HUMMA deep-sea munitions disposal site investigations , 2016 .
[33] I. MacLeod. In-situ Corrosion Measurements of WWII Shipwrecks in Chuuk Lagoon, Quantification of Decay Mechanisms and Rates of Deterioration , 2016, Front. Mar. Sci..
[34] Y. Nakai,et al. NADPH-cytochrome P450 reductase-mediated denitration reaction of 2,4,6-trinitrotoluene to yield nitrite in mammals. , 2016, Free radical biology & medicine.
[35] D. Armbruster,et al. Limit of blank, limit of detection and limit of quantitation. , 2008, The Clinical biochemist. Reviews.
[36] G. Lotufo,et al. Toxicity of explosive compounds to the marine mussel, Mytilus galloprovincialis, in aqueous exposures. , 2007, Ecotoxicology and environmental safety.
[37] Rean Monfils,et al. THE GLOBAL RISK OF MARINE POLLUTION FROM WWII SHIPWRECKS: EXAMPLES FROM THE SEVEN SEAS , 2005 .
[38] J. Sturve,et al. Tentative biomarkers for 2,4,6-trinitrotoluene (TNT) in fish (Oncorhynchus mykiss). , 2005, Aquatic toxicology.
[39] S. Oikawa,et al. 2,4,6-Trinitrotoluene-induced Reproductive Toxicity via Oxidative DNA Damage by its Metabolite , 2002, Free radical research.
[40] Pamela K. Walker,et al. Chemical Sensing of Explosive Targets in the Bedford Basin, Halifax, Nova Scotia , 2001 .
[41] R. Carr,et al. Development of Marine Toxicity Data for Ordnance Compounds , 2001, Archives of environmental contamination and toxicology.
[42] H. Javitz,et al. Toxicity of TNT Wastewaters to Aquatic Organisms. Volume 2. Acute Toxicity of Condensate Wastewater and 2,4-Dinitrotoluene , 1983 .
[43] B. O. Rosseland,et al. Uptake and effects of 2, 4, 6 - trinitrotoluene (TNT) in juvenile Atlantic salmon (Salmo salar). , 2018, Aquatic toxicology.
[44] J. Porter,et al. Ecological, Radiological, and Toxicological Effects of Naval Bombardment on the Coral Reefs of Isla de Vieques, Puerto Rico , 2011 .
[45] G. Machlis,et al. Warfare Ecology , 2008 .
[46] R. Naidu,et al. Explosives: fate, dynamics, and ecological impact in terrestrial and marine environments. , 2007, Reviews of environmental contamination and toxicology.
[47] Volker Harth,et al. Genotoxicity and Potential Carcinogenicity of 2,4,6-Trinitrotoluene: Structural and Toxicological Considerations , 2006, Reviews on environmental health.
[48] M. Stankiewicz. Baltic Marine Environment Protection Commission , 1989 .