Targeted Removal of Bioavailable Metal as a Detoxification Strategy for Carbon Nanotubes.
about
Purification and sidewall functionalization of multiwalled carbon nanotubes and resulting bioactivity in two macrophage modelsRadical scavenging reaction kinetics with multiwalled carbon nanotubesDifferentiation of chemical reaction activity of various carbon nanotubes using redox potential: Classification by physical and chemical structures.A new approach to design safe CNTs with an understanding of redox potentialThe inhibition of neuronal calcium ion channels by trace levels of yttrium released from carbon nanotubesIntracellular fate of carbon nanotubes inside murine macrophages: pH-dependent detachment of iron catalyst nanoparticlesBiochemical and histopathological evaluation of functionalized single-walled carbon nanotubes in Swiss-Webster miceEngineered nanomaterials: exposures, hazards, and risk preventionStudy of hepatotoxicity and oxidative stress in male Swiss-Webster mice exposed to functionalized multi-walled carbon nanotubesEffect of aspect ratio on the uptake and toxicity of hydroxylated-multi walled carbon nanotubes in the nematode, Caenorhabditis elegansMurine pulmonary responses after sub-chronic exposure to aluminum oxide-based nanowhiskersEffect of MWCNT size, carboxylation, and purification on in vitro and in vivo toxicity, inflammation and lung pathologyMulti-walled carbon nanotube-induced inflammatory response and oxidative stress in a dynamic cell growth environmentBiopersistence and potential adverse health impacts of fibrous nanomaterials: what have we learned from asbestos?Antioxidant deactivation on graphenic nanocarbon surfacesBiodurability of Single-Walled Carbon Nanotubes Depends on Surface FunctionalizationChemically reduced graphene contains inherent metallic impurities present in parent natural and synthetic graphiteNanotoxicology: the molecular science point of view.Effect of chemical composition and state of the surface on the toxic response to high aspect ratio nanomaterials.The role of iron impurities in the toxic effects exerted by short multiwalled carbon nanotubes (MWCNT) in murine alveolar macrophages.Length-dependent effect of single-walled carbon nanotube exposure in a dynamic cell growth environment of human alveolar epithelial cells.Purification of carbon nanotubes by high temperature chlorine gas treatment.Pro-inflammatory effects of different MWCNTs dispersions in p16(INK4A)-deficient telomerase-expressing human keratinocytes but not in human SV-40 immortalized sebocytes.Direct determination of bioavailable molybdenum in carbon nanotubes.Acute pulmonary response of mice to multi-wall carbon nanotubes.Detection of single walled carbon nanotubes by monitoring embedded metals.Length, but Not Reactive Edges, of Cup-stack MWCNT Is Responsible for Toxicity and Acute Lung Inflammation.Direct voltammetric determination of redox-active iron in carbon nanotubes.Neurobehavioral toxicity of carbon nanotubes in mice.Ball-milled sulfur-doped graphene materials contain metallic impurities originating from ball-milling apparatus: their influence on the catalytic properties.Short-term splenic impact of single-strand DNA functionalized multi-walled carbon nanotubes intraperitoneally injected in rats.Residual metallic impurities within carbon nanotubes play a dominant role in supposedly "metal-free" oxygen reduction reactions.Graphene oxide nanoribbons from the oxidative opening of carbon nanotubes retain electrochemically active metallic impurities.Redox-active nickel in carbon nanotubes and its direct determination.Nanographite impurities in carbon nanotubes: their influence on the oxidation of insulin, nitric oxide, and extracellular thiols.Voltammetry of carbon nanotubes and graphenes: excitement, disappointment, and reality.Metallic impurities in graphenes prepared from graphite can dramatically influence their properties.Metallic impurities are responsible for electrocatalytic behavior of carbon nanotubes towards sulfides.Impurities within carbon nanotubes govern the electrochemical oxidation of substituted hydrazines.Nanographite impurities of single-walled and double-walled carbon nanotubes are responsible for the observed "electrocatalytic" effect towards the reduction of azo groups.
P2860
Q23919996-508075EA-12CE-42FB-80B5-21D29391D066Q23921449-445BB9FA-7A6C-4015-AA84-7883E4BBEC4EQ23921451-C9AB1FFF-7214-425E-A1E9-1254C41CE112Q23921453-1671CAA9-B6A5-437B-AB9A-DC9E7B5A2C4FQ24645995-E78B5DA2-E1D7-4380-B442-9F19D26D683CQ28384988-E92597B9-5598-435F-8191-A77C10646CC2Q28385331-DD7F263C-CBF8-407A-A346-32E90B842468Q28387517-DE110483-B74E-4A31-884E-86EBC641726FQ28388363-EBC20D08-96A7-4B16-A49B-D98C4AFA1A72Q28390010-9183A3C3-D1ED-416B-B30A-AA6638D48B41Q28390100-1AF5687E-5CF7-42D3-A203-99DED02DE811Q28391128-38A68828-B42F-4B0B-9934-0D18AA0E7D83Q28393482-E75B5B15-551F-4A04-BEB8-FAE733AF301BQ28395275-B8F04468-E8FF-40E8-A8A3-590BB6FE69A2Q28397287-027F0F94-AF42-46B3-B9E7-DB1A46791381Q33751006-25099F05-4ECA-4C92-B5CC-1551BF580894Q36167587-15CF0970-9FD9-476E-99E9-F01D9957B0D4Q37781310-ED2E3D7E-C184-4E9E-A23A-C9A00CE5163AQ37906639-4AA7DB84-CFA6-42C2-9AFC-1725365EF03EQ39067376-E53FBE35-4FF0-435F-91C4-8769E1554C17Q39304031-A1C51F5D-208A-4293-9BD8-FCB7AEA64802Q39455321-861E9949-CF3C-4A59-A8F1-3DEA74B43767Q39586053-EA636F5B-73F9-4CEF-8305-5595E2A48E75Q39788853-CB4F51D8-33D9-4477-B0C5-A323C3349FE2Q39910871-07D988B7-F8A7-4D4C-8FA7-D3C196BBDC6AQ43829726-D42212C7-B2DC-4389-B6F7-6491EA3E9377Q45068348-4B7CF735-7861-494D-A27B-431EC5E5AC3FQ46846627-9C6638BF-618A-488C-89EC-91545650506BQ47426671-2362B763-6BBE-458C-A0CF-8D6831A0CEB1Q50625587-11EF7E0E-61F7-4F75-8869-1EF3CA3C2AB1Q50990679-7FEEDA21-9A6D-4208-8491-79BB082A444DQ51040555-E4C2F104-937A-47B4-A4C7-774C38085DF6Q51205034-C9E22835-A94B-4F35-A7DD-48885CEF26B9Q51429559-C5B604EB-2459-48A9-9806-3DA0B862C0F1Q51458752-7C77B4E9-37E0-4EB0-A07D-10C5A9C0D0F4Q51488448-31812D83-59AD-4485-9941-7BB1951D2942Q51490226-C02A3797-B95D-4DF2-9181-50F53A347AECQ51558425-52394BD1-CFAF-4389-949B-53AAAEF51D9FQ51570693-9F6D249E-A978-4267-8585-55FFA63FDFF0Q51600067-4F573F49-2F0A-4418-89D6-AA52CA82B60C
P2860
Targeted Removal of Bioavailable Metal as a Detoxification Strategy for Carbon Nanotubes.
description
2008 nî lūn-bûn
@nan
2008年の論文
@ja
2008年論文
@yue
2008年論文
@zh-hant
2008年論文
@zh-hk
2008年論文
@zh-mo
2008年論文
@zh-tw
2008年论文
@wuu
2008年论文
@zh
2008年论文
@zh-cn
name
Targeted Removal of Bioavailable Metal as a Detoxification Strategy for Carbon Nanotubes.
@en
Targeted Removal of Bioavailable Metal as a Detoxification Strategy for Carbon Nanotubes.
@nl
type
label
Targeted Removal of Bioavailable Metal as a Detoxification Strategy for Carbon Nanotubes.
@en
Targeted Removal of Bioavailable Metal as a Detoxification Strategy for Carbon Nanotubes.
@nl
prefLabel
Targeted Removal of Bioavailable Metal as a Detoxification Strategy for Carbon Nanotubes.
@en
Targeted Removal of Bioavailable Metal as a Detoxification Strategy for Carbon Nanotubes.
@nl
P2093
P2860
P1433
P1476
Targeted Removal of Bioavailable Metal as a Detoxification Strategy for Carbon Nanotubes.
@en
P2093
Agnes B Kane
Daniel Morris
Robert H Hurt
Xinyuan Liu
P2860
P304
P356
10.1016/J.CARBON.2007.12.018
P577
2008-03-01T00:00:00Z