about
Renal clearance and degradation of glutathione-coated copper nanoparticlesPassive tumor targeting of renal-clearable luminescent gold nanoparticles: long tumor retention and fast normal tissue clearance.Chitosan-capped gold nanoparticles for selective and colorimetric sensing of heparinLuminescent gold nanoparticles: a new class of nanoprobes for biomedical imaging.A resonance light scattering sensor based on methylene blue-sodium dodecyl benzene sulfonate for ultrasensitive detection of guanine base associated mutations.Bioapplications of renal-clearable luminescent metal nanoparticles.Surface-chemistry effect on cellular response of luminescent plasmonic silver nanoparticles.Fluorescent pH-Sensing Probe Based on Biorefinery Wood Lignosulfonate and Its Application in Human Cancer Cell Bioimaging.PEGylation and zwitterionization: pros and cons in the renal clearance and tumor targeting of near-IR-emitting gold nanoparticles.Luminescent Gold Nanoparticles with Size-Independent EmissionGlutathione-coated luminescent gold nanoparticles: a surface ligand for minimizing serum protein adsorption.Luminescent gold nanoparticles with pH-dependent membrane adsorption.High-contrast Noninvasive Imaging of Kidney Clearance Kinetics Enabled by Renal Clearable Nanofluorophores.One-step interfacial synthesis and assembly of ultrathin luminescent AuNPs/silica membranes.Tailor-made Au@Ag core-shell nanoparticle 2D arrays on protein-coated graphene oxide with assembly enhanced antibacterial activity.Rapid and sensitive determination of proteins by enhanced resonance light scattering spectroscopy of sodium lauroyl glutamate.Resonance light scattering spectroscopy of beta-cyclodextrin-sodium dodecylsulfate-protein ternary system and its analytical applications.Mercaptosuccinic acid-coated NIR-emitting gold nanoparticles for the sensitive and selective detection of Hg2.Reactivity Toward Ag+: A General Strategy to Generate a New Emissive Center from NIR-Emitting Gold Nanoparticles.Coordinatively Self-Assembled Luminescent Gold Nanoparticles: Fluorescence Turn-On System for High-Efficiency Passive Tumor Imaging.pH-Guided Self-Assembly of Copper Nanoclusters with Aggregation-Induced Emission.Coordination-induced decomposition of luminescent gold nanoparticles: sensitive detection of H2O2 and glucose.High-sensitivity determination of curcumin in human urine using gemini zwitterionic surfactant as a probe by resonance light scattering technique.Micro-determination of nucleic acids with a simple probe manganese chloride based on the fine enhanced resonance light scatteringDevelopment of a sensitive and rapid nucleic acid assay with tetraphenyl porphyrinatoiron chloride by a resonance light scattering techniqueA sensitive rutin assay using a simple probe manganese sulfate based on its novel resonance light scattering decrease phenomenonA novel and selective assay for the quantitative analysis of molybdenum(VI) at nanogram level by resonance light scattering quenching techniqueUse of sodium lauroyl sarcosinate in a high-sensitivity protein assay by resonance light scattering techniqueAn aptamer based resonance light scattering assay of prostate specific antigenToward a universal "adhesive nanosheet" for the assembly of multiple nanoparticles based on a protein-induced reduction/decoration of graphene oxideNear-infrared emitting radioactive gold nanoparticles with molecular pharmacokineticsBidirectional Regulation of Singlet Oxygen Generation from Luminescent Gold Nanoparticles through Surface ManipulationSurface Coverage-Regulated Cellular Interaction of Ultrasmall Luminescent Gold NanoparticlesAmphiphilic Block Copolymer-Guided in Situ Fabrication of Stable and Highly Controlled Luminescent Copper NanoassembliesSelf-Assembly of Luminescent Gold Nanoparticles with Sensitive pH-Stimulated Structure Transformation and Emission Response toward Lysosome Escape and Intracellular ImagingFacile in situ synthesis of ultrasmall near-infrared-emitting gold glyconanoparticles with enhanced cellular uptake and tumor targeting
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Q28829398-E0379300-9A95-48C6-B125-74001058A720Q34023045-5C30820B-41C9-4E76-B2F3-B9B6E73F8045Q37196345-2F1E15A8-78D5-46F5-A717-BFF56529FE82Q38151020-0A23A0D9-82E4-419B-8D3F-2FEF2939629FQ38322734-C3F9F79F-4352-4B5A-8F8E-50B8B6E650DBQ38686196-7F4F10F8-9285-444F-8DA9-A2DF6F20F23EQ38701931-DE3711AC-33DE-4CAA-8908-1911570A4279Q38726278-874B3BBE-661B-4FBD-8150-CC7DAEC16211Q39079349-A42CD78F-4A24-4807-87FF-C07E51136EF3Q41540505-9FD1A6B2-EF46-428B-9F7D-8AFF8451A7D7Q41780540-ECE3FC6F-4338-4306-BF69-99440D2AF9D8Q42211944-D53BD73F-F201-439E-AFE5-55E326023481Q43075040-E80DCBF8-E169-426C-BC0D-0539A15C1493Q43245900-048AC8A4-25F2-4A34-99F2-D3C7A9749993Q45255884-50F959EF-21D8-4C2D-9AA3-8CE35D35B327Q46205033-226A2120-1B37-4276-8B83-AADCACBDA4F2Q46902940-9BE09902-A29E-431D-AC18-322B4394583CQ47862164-17DD9D16-BBBF-4EC4-A163-04D3FE6DF8CDQ48233771-CC16F5B5-C69E-4140-8DAD-8DCDE74AC5E4Q48330447-4CD6A998-AD7E-4E0A-89FF-6ABE03BAF712Q48373119-205F1D56-01DF-4B80-895A-6CA8D8E94632Q48909070-AD2A64C8-6043-4083-A0AF-72E8DE9BB121Q51466884-2ED14529-2CEB-475F-B9FD-1AC0E31DE683Q79842369-E3CE9732-AF75-4785-88E6-B68C53B91E95Q80566063-0F03685A-B876-449D-B547-DD63F6A0E5ECQ80726672-D41F9720-16A2-42A8-9267-277001682612Q81297279-491C936C-2FC9-4801-81BC-9DE076CA593FQ83918004-6A93FE74-4A63-4DF0-B6BC-4776F7786D8AQ84030598-BAD72CCD-085E-4089-8E6A-CEA86230F3EDQ84207859-47F2C775-9C96-4AA0-8C7C-FAF0161CFB07Q84954543-98E411A5-4CE9-4A20-BA80-1251F6E0B64BQ90340336-6D8D2A3D-FAE6-4958-A8A3-CF7755C56F51Q91289747-D9A685F9-38B7-429A-AAFF-48180D5864B8Q91337225-976B5D53-01FD-43CF-8B9D-430E14A67280Q92332457-6CFF0DFA-5BED-4DEB-B63F-01DE11D63937Q92915034-91E09026-AE76-4BD6-B0D3-698FC84C0173
P50
description
onderzoeker
@nl
researcher
@en
հետազոտող
@hy
name
Jinbin Liu
@ast
Jinbin Liu
@en
Jinbin Liu
@es
Jinbin Liu
@sl
type
label
Jinbin Liu
@ast
Jinbin Liu
@en
Jinbin Liu
@es
Jinbin Liu
@sl
prefLabel
Jinbin Liu
@ast
Jinbin Liu
@en
Jinbin Liu
@es
Jinbin Liu
@sl
P1053
B-2743-2013
P106
P1153
57189729492
P31
P3829
P496
0000-0002-2046-131X