%D8%B9%D9%84%D9%85_%D8%A7%D9%84%D8%B3%D9%85%D9%88%D9%85_%D8%A7%D9%84%D9%86%D8%A7%D9%86%D9%88%D9%8ACategory:NanotoxicologyNanotoxicologyNanotoxicolog%C3%ADaNanotoksikoloogiaNanotoxicologie%D7%A0%D7%A0%D7%95-%D7%98%D7%95%D7%A7%D7%A1%D7%99%D7%A7%D7%95%D7%9C%D7%95%D7%92%D7%99%D7%94NanotoksikologiNanotossicologiaNanopathologiaQ2518429
about
P101
Mechanisms of pulmonary toxicity and medical applications of carbon nanotubes: two faces of Janus?Nanotoxicology - a pathologist's perspectiveNanoparticulatesClose encounters of the small kind: adverse effects of man-made materials interfacing with the nano-cosmos of biological systemsApplied nanotoxicologyMyD88 mediates in vivo effector functions of alveolar macrophages in acute lung inflammatory responses to carbon nanotube exposurePsychosocial job factors and biological cardiovascular risk factors in Mexican workersSmall airway epithelial cells exposure to printer-emitted engineered nanoparticles induces cellular effects on human microvascular endothelial cells in an alveolar-capillary co-culture modelPathologic and molecular profiling of rapid-onset fibrosis and inflammation induced by multi-walled carbon nanotubesAdvances in mechanisms and signaling pathways of carbon nanotube toxicitySuppression of basal and carbon nanotube-induced oxidative stress, inflammation and fibrosis in mouse lungs by Nrf2Tracking translocation of industrially relevant engineered nanomaterials (ENMs) across alveolar epithelial monolayers in vitroDynamic oversight: implementation gaps and challengesA new stochastic kriging method for modeling multi-source exposure-response data in toxicology studiesThe effect of cerium oxide nanoparticle valence state on reactive oxygen species and toxicityEvaluation of the effect of valence state on cerium oxide nanoparticle toxicity following intratracheal instillation in ratsEngineered carbonaceous nanomaterials manufacturers in the United States: workforce size, characteristics, and feasibility of epidemiologic studiesIn vivo evaluation of the pulmonary toxicity of cellulose nanocrystals: a renewable and sustainable nanomaterial of the futureEngineered nanoparticle respiratory exposure and potential risks for cardiovascular toxicity: predictive tests and biomarkersImpairment of coronary arteriolar endothelium-dependent dilation after multi-walled carbon nanotube inhalation: a time-course studyGeneration of reactive oxygen species from silicon nanowiresEffects of nickel-oxide nanoparticle pre-exposure dispersion status on bioactivity in the mouse lung"Real-world" precision, bias, and between-laboratory variation for surface area measurement of a titanium dioxide nanomaterial in powder formThe Nanotoxicology Research Program in NIOSHNanoparticles as an emerging environmental and occupational hazard: does oxidative stress matter?Silicon nanowires: free radical production and related damage in cellular exposuresNanotoxicology: "the end of the beginning" - signs on the roadmap to a strategy for assuring the safe application and use of nanomaterialsToxic effects of carbon nanotubes in macrophage and bronchial epithelium cell culturesDirect stimulation of human fibroblasts by nCeO2 in vitro is attenuated with an amorphous silica coatingNanotoxicology ten years later: lights and shadowsHow should the completeness and quality of curated nanomaterial data be evaluated?Miniature differential mobility analyzer for compact field-portable spectrometersIn vitro toxicity evaluation of lignin-(un)coated cellulose based nanomaterials on human A549 and THP-1 cellsMicrosomal glutathione transferase 1 protects against toxicity induced by silica nanoparticles but not by zinc oxide nanoparticlesNanosilver induces minimal lung toxicity or inflammation in a subacute murine inhalation modelMurine pulmonary responses after sub-chronic exposure to aluminum oxide-based nanowhiskersEffect of antioxidants on enzyme-catalysed biodegradation of carbon nanotubesInflammatory response of mice following inhalation exposure to iron and copper nanoparticlesOxidative stress, DNA methylation, and telomere length changes in peripheral blood mononuclear cells after pulmonary exposure to metal-rich welding nanoparticlesHazard and Risk Assessment of Workplace Exposure to Engineered Nanoparticles: Methods, Issues, and Carbon Nanotube Case Study (second edition)
P921
Q23909384-7A748AF2-E51B-4081-84E9-99EDA0AD6047Q23909944-B4B04109-F4FD-480A-9F79-0412F163D07FQ23909949-8812F49A-99C2-4183-BAB4-0A105E282175Q23909985-73F6D2A9-9054-4967-978E-8C9AE21A1DC5Q23911868-59753037-3491-4417-A4BB-9D43F62EED9DQ23912746-6F3B5742-F7DC-4DA9-BF96-F46FAF2A78F6Q23913767-CAAEA541-2DC9-412C-9A40-EAF092DC0F35Q23914652-4622E97E-F178-4827-AB81-59E5ACCEE019Q23914873-A90F629C-0775-4633-B869-2EBE0037DB27Q23914875-44072DAB-688C-4995-B3D8-8BF5AF67112DQ23914877-9D569634-6B87-4036-89D7-870B8414F7DEQ23915033-7FC5AF36-6275-4344-885E-1AD7463E6AC1Q23915163-49E7BAFF-CC1A-4184-A9D0-DAF7A1956811Q23915831-17539C14-7E60-44E9-89C4-92C23CBBB26AQ23915935-36642848-B3CC-46E5-B30C-0A61CF2B7718Q23915937-E02F701C-FA08-4D9E-A5DD-A3A1D1A88398Q23917967-DC024204-FAFB-48D3-9106-C0A4E2763AFDQ23918815-B43C0EF1-9A8D-4B4E-9F06-B0FBF04E8E8EQ23919501-52C5E5AC-36E9-4816-A299-3893F499EAFAQ23919580-8B1AABFA-B29B-4AB6-BFCD-93B4BE4CB71FQ23921757-7270C61D-C7EB-4BF8-854F-F28C25BC8199Q23922862-49277AA9-14CF-41A3-B20E-A186C79281B1Q23923323-6DE89DF0-8CBE-462A-85B4-0C25A9DE01A2Q23923327-DF9EDB99-5BAC-43B9-88B3-8E326032EC8DQ24354584-A7ED8A38-199D-4BB4-BC29-33CFEF0BE7FBQ24718992-D81B0372-B2E2-489A-AE69-2F6F323529E8Q24853216-D35C397C-6C74-4DBD-B76A-95AE6D502F08Q26206306-55C3D74A-2AA0-4899-854F-2253281D3193Q26343837-ED12A1D6-25EF-498F-9161-ECAE59AA8EC3Q26345188-736F26BE-D85D-4211-9060-4BE5EDD642E2Q27908490-1AF4AEA5-F214-436D-8767-1C7C347B5665Q27908498-96C870BB-CC44-4D5C-8BE1-58711FE2B0BAQ27968950-08DEC254-8C87-4EA2-9502-9A8F527B792AQ28382868-495C671F-C204-4BEA-AA3B-239CC1666024Q28386312-641B8CD2-74D4-4CC1-BB73-441B4BEFF5AFQ28390100-873AA870-8E5A-4DCF-96B4-B403458BCE63Q28397275-CA411B61-9687-4A44-ABEE-2224AF4231B5Q28950523-5E8AA2DA-9D6C-46AA-829E-365C744E38CDQ28950608-1DDFAE0D-96E4-4D81-B84F-A1C4E22D2E06Q28950737-75175C3B-0D97-4766-9AFB-E85CE62BE47B
P921
description
Unterklasse der Toxikologie
@de
study of the toxicity of nanomaterials
@en
name
Nanopathologia
@la
Nanotoksikologi
@id
Nanotoksikoloogia
@et
Nanotossicologia
@it
nanotoxicologie
@fr
nanotoxicology
@en
nanotoxicología
@es
ננו טוקסיקולוגיה
@he
علم السموم النانوي
@ar
ナノ毒性
@ja
type
label
Nanopathologia
@la
Nanotoksikologi
@id
Nanotoksikoloogia
@et
Nanotossicologia
@it
nanotoxicologie
@fr
nanotoxicology
@en
nanotoxicología
@es
ננו טוקסיקולוגיה
@he
علم السموم النانوي
@ar
ナノ毒性
@ja
altLabel
Nanopatologia
@it
Nanopatologie
@it
nanotoxicité
@fr
nanotoxicologia
@es
nanotoxique
@fr
ננו-טוקסיקולוגיה
@he
ננוטוקסיקולוגיה
@he
ナノトキシコロジー
@ja
prefLabel
Nanopathologia
@la
Nanotoksikologi
@id
Nanotoksikoloogia
@et
Nanotossicologia
@it
nanotoxicologie
@fr
nanotoxicology
@en
nanotoxicología
@es
ננו טוקסיקולוגיה
@he
علم السموم النانوي
@ar
ナノ毒性
@ja
P6366
P646
P373
Nanotoxicology
P6366
P646
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