2016 RECORDS FOUND
INDEX | TITLE | AUTHORS | PUBLICATION | ABSTRACT |
---|---|---|---|---|
22/02 | Crosstalk between gut microbiota and lung inflammation in murine toxicity models of respiratory exposure or co-exposure to carbon nanotube particles and cigarette smoke extract. | Bhattacharya,S.S.; Yadav,B.; Rosen,L.; Nagpal,R.; Yadav,H.; Yadav,J.S. | Toxicology and Applied Pharmacology, 447. | abstract |
22/01 | The health effects of short fiber chrysotile and amphibole asbestos. | Bernstein, D.M. | Critical Reviews in Toxicology, 52(2): 89-112. | paper |
21/54 | Serum peptidome: diagnostic window into pathogenic processes following occupational exposure to carbon nanomaterials | Mostovenko,E.; Dahm,M.M.; Schubauer-Berigan,M.K.; Eye,T.; Erdely,A.; Young,T.L.; Campen,M.J.; Ottens,A.K. | Particle and Fibre Toxicology, 18(1). | paper |
21/53 | Genotoxicity of multi-walled carbon nanotube reference materials in mammalian cells and animals. | Møller,P.; Wils,R.S.; Di Ianni,E.; Gutierrez,C.A.T.; Roursgaard,M.; Jacobsen,N.R. | Mutation Research/Reviews in Mutation Research, 788: 108393. | paper |
21/52 | Respiratory and systemic impacts following MWCNT inhalation in B6C3F1/N mice. | Migliaccio,C.T.; Hamilton,R.F., Jr.; Shaw,P.K.; Rhoderick,J.F.; Deb,S.; Bhargava,R.; Harkema,J.R.; Holian,A. | Particle and Fibre Toxicology, 18(1). | paper |
21/51 | Multi-walled carbon nanotubes trigger lysosome-dependent cell death (pyroptosis) in macrophages but not in neutrophils. | Keshavan,S.; Gupta,G.; Martin,S.; Fadeel,B. | Nanotoxicology, 15(9). | paper |
21/50 | Transcriptome Profile Alterations with Carbon Nanotubes, Quantum Dots, and Silver Nanoparticles: A Review. | Horstmann,C.; Davenport,V.; Zhang,M.; Peters,A.; Kim,K. | Genes, 12(6): 10.3390/genes12060794. | paper |
21/49 | Histopathology of the broad class of carbon nanotubes and nanofibers used or produced in U.S. facilities in a murine model. | Fraser,K.; Hubbs,A.; Yanamala,N.; Mercer,R.R.; Stueckle,T.A.; Jensen,J.; Eye,T.; Battelli,L.; Clingerman,S.; Fluharty,K.; Dodd,T.; Casuccio,G.; Bunker,K.; Lersch,T.L.; Kashon,M.L.; Orandle,M.; Dahm,M.; Schubauer-Berigan,M.K.; Kodali,V.; Erdely,A. | Particle and Fibre Toxicology, 18(1). | paper |
21/48 | Nanomaterial- and shape-dependency of TLR2 and TLR4 mediated signaling following pulmonary exposure to carbonaceous nanomaterials in mice. | Danielsen,P.H.; Bendtsen,K.M.; Knudsen,K.B.; Poulsen,S.S.; Stoeger,T.; Vogel,U. | Particle and Fibre Toxicology, 18(1). | paper |
21/47 | Retained particle surface area dose drives inflammation in rat lungs following acute, subacute, and subchronic inhalation of nanomaterials. | Cosnier,F.; Seidel,C.; Valentino,S.; Schmid,O.; Bau,S.; Vogel,U.; Devoy,J.; Gaté,L. | Particle and Fibre Toxicology, 18(1). | paper |
21/46 | Rounded atelectasis after exposure to refractory ceramic fibres (RCF). | Brueckner,U.; Schulze,A.S.; Walter,D.; Kampschulte,M.; Schneider,J. | Particle and Fibre Toxicology, 18(1). | paper |
21/45 | Lipid peroxidation metabolites associated with biomarkers of inflammation and oxidation stress in workers handling carbon nanotubes and metal oxide nanoparticles. | Wu,W.T.; Jung,W.T.; Lee,H.L. | Nanotoxicology, 15(5): 577-587. | abstract |
21/44 | Inflammatory Response, Reactive Oxygen Species Production and DNA Damage in Mice after Intrapleural Exposure to Carbon Nanotubes. | Wils,R.Sø.; Jacobsen,N.R.; Vogel,U.; Roursgaard,M.; Møller,P. | Toxicological Sciences, 183(1): 184-194. | abstract |
21/43 | Reactive oxygen species production, genotoxicity and telomere length in FE1-Muta™Mouse lung epithelial cells exposed to carbon nanotubes. | Wils,R.S.; Jacobsen,N.R.; Di Ianni,E.; Roursgaard,M.; Møller,P. | Nanotoxicology, 15(5): 661-672. | abstract |
21/42 | Toxicity evaluation of mesoporous silica particles Santa Barbara No. 15 amorphous in human umbilical vein endothelial cells: influence of particle morphology | Teng,W.; Yang,Z.; Wang,S.; Xiong,D.; Chen,Y.; Wu,Z. | Journal of Applied Toxicology, 41(9): 1467-1478. | abstract |
21/41 | Reply to the Comment on Critical Choices in Predicting Stone Wool Biodurability: Lysosomal Fluid Compositions and Binder Effects. | Sauer,U.G.; Werle,K.; Waindok,H.; Hirth,S.; Hachmöller,O.; Wohlleben,W. | Chemical Research in Toxicology, 34(7): 1697-1698. | paper |
21/40 | Critical Choices in Predicting Stone Wool Biodurability: Lysosomal Fluid Compositions and Binder Effects. | Sauer, U.G; Werle, K.; Waindok, H.; Hirth, S.; Hachmöller, O.; Wohlleben, W. | Chemical Research in Toxicology, 34(3): 780-792. | abstract |
21/39 | Assessment of the Skin and Heart Tissue Damage Following Inhalation of Carbon Nanotubes in Wistar Rats Using Isolated Mitochondria. | Samiei, F.; Seydi, E.; Dousti, F.; Hayati, A.; H Shirazi, F.; Pourahmad Jaktaji, J. | Iranian Journal of Pharmaceutical Sciences, 17(1): 69-78. | paper |
21/38 | Cellular senescence as a response to multiwalled carbon nanotube (MWCNT) exposure in human mesothelial cells. | Reamon-Buettner,S.M.; Hackbarth,A.; Leonhardt,A.; Braun,A.; Ziemann,C. | Mechanisms of Ageing and Development, 193: 111412. | abstract |
21/37 | Multiple pathways of alveolar macrophage death contribute to pulmonary inflammation induced by silica nanoparticles. | Park,E.J.; Kang,M.S.; Jin,S.W.; Lee,T.G.; Lee,G.H.; Kim,D.W.; Lee,E.W.; Park,J.; Choi,I.; Pak,Y.K. | Nanotoxicology, 15(8): 1087-1101. | abstract |
21/36 | Carbon Nanotube Exposure Triggers a Cerebral Peptidomic Response: Barrier Compromise, Neuroinflammation, and a Hyperexcited State. | Mostovenko,E.; Saunders,S.; Muldoon,P.P.; Bishop,L.; Campen,M.J.; Erdely,A.; Ottens,A.K. | Toxicological Sciences, 182(1): 107-119. | paper |
21/35 | Health effects after inhalation of micro- and nano-sized zinc oxide particles in human volunteers. | Monse,C.; Raulf,M.; Jettkant,B.; van Kampen,V.; Kendzia,B.; Schurmeyer,L.; Seifert,C.E.; Marek,E.M.; Westphal,G.; Rosenkranz,N.; Merget,R.; Bruning,T.; Bunger,J. | Archives of Toxicology, 95(1): 53-65 | paper |
21/34 | Emissions and exposures of graphene nanomaterials, titanium dioxide nanofibers, and nanoparticles during down-stream industrial handling. | Loven,K.; Franzen,S.M.; Isaxon,C.; Messing,M.E.; Martinsson,J.; Gudmundsson,A.; Pagels,J.; Hedmer,M.; NanoLund | Journal of Exposure Science & Environmental Epidemiology, 31(4): 736-752 | paper |
21/33 | Quality assurance for nanomaterial inhalation toxicity testing | Lee,S.K.; Jo,M.S.; Kim,H.P.; Kim,J.C.; Yu,I.J. | Inhalation Toxicology, 33(5): 161-167. | abstract |
21/32 | miR221 regulates cell migration by targeting annexin a1 expression in human mesothelial MeT-5A cells neoplastic-like transformed by multi-walled carbon nanotube | Ju,L.; Zhu,L.; Wu,H.; Yu,M.; Yin,X.; Jia,Z.; Feng,L.; Ying,S.; Xia,H.; Zhang,S.; Lou,J.; Yang,J. | Genes and Environment : The Official Journal of the Japanese Environmental Mutagen Society, 43(1): 34-021-00209-y. | paper |
21/31 | Safe-by-design strategies for lowering the genotoxicity and pulmonary inflammation of multiwalled carbon nanotubes: Reduction of length and the introduction of COOH groups. | Hadrup,N.; Knudsen,K.B.; Carriere,M.; Mayne-L’Hermite,M.; Bobyk,L.; Allard,S.; Miserque,F.; Pibaleau,B.; Pinault,M.; Wallin,H.; Vogel,U. | Environmental Toxicology and Pharmacology, 87: 103702. | paper |
21/30 | Adaption of Lung Fibroblasts to Fluoro-Edenite Fibers: Evaluation of Molecular and Physiological Dynamics. | Graziano,A.C.E.; Ledda,C.; Loreto,C.; Cardile,V. | Cellular Physiology and Biochemistry : International Journal of Experimental Cellular Physiology, Biochemistry, and Pharmacology, 55(3): 327-343. | paper |
21/29 | Length difference of multi-walled carbon nanotubes generates differential cytotoxic responses | Do,N.T.; Kim,S.; Kwak,M.; Lee,T.G.; Jo,D.-G.; Lee,S.-W.; Kim,S.-H. | Journal of Applied Toxicology, 41(9): 1414-1424. | abstract |
21/28 | In vitro-in vivo correlations of pulmonary inflammogenicity and genotoxicity of MWCNT | Di Ianni,E.; Erdem,J.S.; Moller,P.; Sahlgren,N.M.; Poulsen,S.S.; Knudsen,K.B.; Zienolddiny,S.; Saber,A.T.; Wallin,H.; Vogel,U.; Jacobsen,N.R. | Particle and Fibre Toxicology, 18(1): 25-021-00413-2. | paper |
21/27 | Statins repress needle-like carbon nanotube- or cholesterol crystal-stimulated IL-1β production by inhibiting the uptake of crystals by macrophages. | Cui,H.; Soga,K.; Tamehiro,N.; Adachi,R.; Hachisuka,A.; Hirose,A.; Kondo,K.; Nishimaki-Mogami,T. | Biochemical Pharmacology, 188. | abstract |