Regulatory peptides are susceptible to oxidation by metallic impurities within carbon nanotubes.
about
Safe clinical use of carbon nanotubes as innovative biomaterialsChemical basis of interactions between engineered nanoparticles and biological systemsBiotin-modified glutathione as a functionalized coating for bioconjugation of CdTe-based quantum dots.Synthetic routes contaminate graphene materials with a whole spectrum of unanticipated metallic elements.Chemically reduced graphene contains inherent metallic impurities present in parent natural and synthetic graphiteNanotoxicology: the molecular science point of view.Graphene and graphene-based nanomaterials: the promising materials for bright future of electroanalytical chemistry.Recent development of carbon electrode materials and their bioanalytical and environmental applications.Chemical mechanisms of the toxicological properties of nanomaterials: generation of intracellular reactive oxygen species.Metallic impurities availability in reduced graphene is greatly enhanced by its ultrasonication.Purification of carbon nanotubes by high temperature chlorine gas treatment.Direct determination of bioavailable molybdenum in carbon nanotubes.An iron impurity in multiwalled carbon nanotube complexes with chitosan that biomimics the heme-peroxidase function.Residual metallic impurities within carbon nanotubes play a dominant role in supposedly "metal-free" oxygen reduction reactions.Towards electrochemical purification of chemically reduced graphene oxide from redox accessible impurities.Graphene oxide nanoribbons from the oxidative opening of carbon nanotubes retain electrochemically active metallic impurities.Could carbonaceous impurities in reduced graphenes be responsible for some of their extraordinary electrocatalytic activities?Bioavailability of metallic impurities in carbon nanotubes is greatly enhanced by ultrasonication.Metal-based impurities in graphenes: application for electroanalysis.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.Nanomaterials meet microfluidics.Metallic impurities are responsible for electrocatalytic behavior of carbon nanotubes towards sulfides.Impurities within carbon nanotubes govern the electrochemical oxidation of substituted hydrazines.Signal transducers and enzyme cofactors are susceptible to oxidation by nanographite impurities in carbon nanotube materials.Nanographite impurities of single-walled and double-walled carbon nanotubes are responsible for the observed "electrocatalytic" effect towards the reduction of azo groups.Hydroquinone electrochemistry on carbon nanotubes is accelerated by nanographite impurities.Selective and low potential electrocatalytic oxidation and sensing of l-cysteine using metal impurity containing carbon black modified electrodePrussian Blue Modified Solid Carbon Nanorod Whisker Paste Composite Electrodes: Evaluation towards the Electroanalytical Sensing ofH2O2
P2860
Q26851720-9C9BF4CD-05E5-40DA-9615-BFF53A70826BQ27021154-242AEB61-0A30-4C77-897C-9BBCDC7C8E7CQ33910087-830EAD26-C944-4A08-94B0-F5FF0E5449CEQ34281141-1A35404C-E396-424C-82C0-C149AAD1BE48Q36167587-BE841967-C9AB-472F-B226-CB79BBBB0607Q37781310-C4CA67F1-C01D-46CF-980C-ECE5C81AE993Q37942746-4A74183D-B4E5-4009-A662-9430E610603BQ38667937-763F3048-9782-43D4-A2CC-60AA65BA7D59Q39121005-7FAD7150-BD5B-4D89-9595-E002817381F9Q39263242-95BE1DC4-8945-4AB6-B462-550F1173D6FDQ39455321-48114FBE-B548-466D-BD6C-D6FB871F793EQ39788853-9367A00A-193A-4B42-A9CE-859F87291893Q45144483-BB3418D2-74A6-4F72-85D9-A6F901FE7770Q51040555-D799B9EF-49D4-4279-AC11-37548D6926EFQ51103048-EE1D451C-F62F-4C8A-8429-CCE33BA1FF33Q51205034-AAAB050A-DEF2-49CB-85A2-5F881073629EQ51242645-93D16302-D2EA-4486-B358-B3367B5DDB6DQ51336842-ABCBB0F7-CA54-4E33-89C0-F6A39554D5B4Q51404004-368BD0B5-241D-406C-B187-F2D33DB9011AQ51429559-90C0FC38-C1D0-48B3-AFC7-C7EF69D3996EQ51458752-4FD29784-5FFF-4530-8664-A21FCDE634F7Q51488448-D2246989-2AD4-4060-8962-FD606D7A52BBQ51490226-5F308CBA-D04F-48F1-A77D-B833365BE28AQ51549743-10E47B56-BD5F-484A-B533-4F5787D41769Q51558425-BD23750B-6157-4B80-9D02-AC39E12F0967Q51570693-89B88259-81EE-475A-8B5B-A27071D6BBA7Q51579077-200AAE39-9AB4-4B8B-B711-7A9EAFAB4680Q51600067-99049BC3-FE03-4B1D-A37D-077A897D81CEQ51611208-A669B8CC-381F-486A-AB78-3C2E3317B979Q58376630-69BF81C7-F0B4-4263-9FF9-117A55E90928Q58703465-1A8F09A1-502F-43B4-81A5-68D3426EF34A
P2860
Regulatory peptides are susceptible to oxidation by metallic impurities within carbon nanotubes.
description
2010 nî lūn-bûn
@nan
2010年の論文
@ja
2010年学术文章
@wuu
2010年学术文章
@zh
2010年学术文章
@zh-cn
2010年学术文章
@zh-hans
2010年学术文章
@zh-my
2010年学术文章
@zh-sg
2010年學術文章
@yue
2010年學術文章
@zh-hant
name
Regulatory peptides are suscep ...... ities within carbon nanotubes.
@en
Regulatory peptides are suscep ...... ities within carbon nanotubes.
@nl
type
label
Regulatory peptides are suscep ...... ities within carbon nanotubes.
@en
Regulatory peptides are suscep ...... ities within carbon nanotubes.
@nl
prefLabel
Regulatory peptides are suscep ...... ities within carbon nanotubes.
@en
Regulatory peptides are suscep ...... ities within carbon nanotubes.
@nl
P356
P1476
Regulatory peptides are suscep ...... ities within carbon nanotubes.
@en
P304
P356
10.1002/CHEM.200902534
P407
P577
2010-02-01T00:00:00Z