Minimizing the hydrodynamic size of quantum dots with multifunctional multidentate polymer ligands
about
Next-generation quantum dotsCompact biocompatible quantum dots via RAFT-mediated synthesis of imidazole-based random copolymer ligandQuantum dots as a platform for nanoparticle drug delivery vehicle designNanoparticles for Improving Cancer Diagnosis.Brightness-equalized quantum dotsIron oxide nanoparticles protected by NIR-active multidentate-polymers as multifunctional nanoprobes for NIRF/PA/MR trimodal imaging.Proton-Resistant Quantum Dots: Stability in Gastrointestinal Fluids and Implications for Oral Delivery of Nanoparticle Agents.Nanoparticle-based theranostic agentsCompact and blinking-suppressed quantum dots for single-particle tracking in live cells.Designing multifunctional quantum dots for bioimaging, detection, and drug deliveryTwo-photon excited quantum dots with compact surface coatings of polymer ligands used as an upconversion luminescent probe for dopamine detection in biological fluids.Quantum dots find their stride in single molecule tracking.Semiconductor quantum dots for biomedicial applicationsAddressing Key Technical Aspects of Quantum Dot Probe Preparation for BioassaysReal-Time Imaging Reveals Local, Transient Vascular Permeability, and Tumor Cell Intravasation Stimulated by TIE2hi Macrophage-Derived VEGFA.Semiconductor quantum dots for bioimaging and biodiagnostic applications.Biocompatible quantum dots for biological applications.Single molecule studies of homologous recombination.Overview of stabilizing ligands for biocompatible quantum dot nanocrystals.Toxico-/biokinetics of nanomaterials.Polymer-coated quantum dots.Biocompatible polymer/quantum dots hybrid materials: current status and future developmentsSplit-inteins for simultaneous, site-specific conjugation of quantum dots to multiple protein targets in vivo.Water-soluble multidentate polymers compactly coating Ag2S quantum dots with minimized hydrodynamic size and bright emission tunable from red to second near-infrared region.Quantum Dot Surface Engineering: Toward Inert Fluorophores with Compact Size and Bright, Stable Emission.Small and stable phosphorylcholine zwitterionic quantum dots for weak nonspecific phagocytosis and effective Tat peptide functionalization.Stable, compact, bright biofunctional quantum dots with improved peptide coatingImaging dynamic cellular events with quantum dots The bright future.Compact quantum dots for single-molecule imagingUnderstanding and overcoming major barriers in cancer nanomedicine.Bright and compact alloyed quantum dots with broadly tunable near-infrared absorption and fluorescence spectra through mercury cation exchangeSemiconductor Nanocrystals Hybridized with Functional Ligands: New Composite Materials with Tunable Properties.Fabrication of bright and small size semiconducting polymer nanoparticles for cellular labelling and single particle tracking.Crosslinked dendronized polyols as a general approach to brighter and more stable fluorophores.A fast synthesis of near-infrared emitting CdTe/CdSe quantum dots with small hydrodynamic diameter for in vivo imaging probes.Synthesis and application of a targeting diagnosis system via quantum dots coated by amphiphilic polymer for the detection of liver cancer cells.A primer on the synthesis, water-solubilization, and functionalization of quantum dots, their use as biological sensing agents, and present status.One-Pot Encapsulation of Luminescent Quantum Dots Synthesized in Aqueous Solution by Amphiphilic PolymersSmart photoluminescent nanohybrids based on CdSe quantum dots capped with multidentate thiolated pH-responsive and thermoresponsive polymers for nanosensingRevisiting the principles of preparing aqueous quantum dots for biological applications: the effects of surface ligands on the physicochemical properties of quantum dots
P2860
Q24594945-1FA19329-B9C9-4978-8758-E111471C6F55Q24615930-554E552A-FAE5-4126-A629-1D06F190A6A4Q26996556-44A757E5-AD8B-431D-A4E0-9715163F26CEQ30442412-D4AC2FBB-6AC9-46BE-85A6-C810AF01D78BQ30666943-B676CB79-B27E-4850-8565-726E95211B78Q31031697-F65A081A-68D1-4A3C-B08E-9145E67B2E9FQ33773035-16842037-3105-4937-8EE2-8CAFAE6D12ADQ34130095-8042BEE2-3E64-440C-835D-B84BF8FDC5D6Q34435205-B86B5BFF-890D-4B69-A800-8D60F01A1F38Q35538371-0F369CC5-4C79-442E-8E2C-4349C02E22A6Q35561815-EC0025BA-07A5-4B8B-BFE2-99620019DBC4Q35613093-34184B41-F79D-4AA1-93A1-F79B0A358CC6Q35654496-C841991A-5243-4E98-941C-832AFBFAFA50Q35866272-CE309763-7D49-4D63-9A23-B8AC9E31CF43Q36029752-1F91B11D-F783-4809-9B1A-74438B021389Q37070798-722BCA67-F797-4B51-B3BD-4B523D151C2EQ37120089-EDB3ADFB-B2D1-421A-83B4-1E18092C6A8CQ37302780-6F087FCD-1E48-44BF-82C6-28285FE76740Q37976071-8D99E17E-78B2-49B6-9245-2AABDB043771Q38009230-84DAB5E3-AE82-4C9D-9BB0-F9D89B51845AQ38153656-E79E0AFF-AC9E-466E-A6F3-A2D38992A070Q38222530-35AFB639-E0B5-4F7E-892C-E07556D78591Q38752837-28DB48BB-6EC7-4F61-B499-1D06EC7032ABQ39004640-EEACE0E9-A840-4FBE-9110-96A312028F2AQ39201415-517E6963-10AE-4649-B32B-7DB9CAEBE802Q39237632-5B8CCAD6-3BB7-4F08-BA3E-52C746F4B4CAQ39295920-C0A1BABD-074C-4EAA-AD72-A3F666499A9CQ39840061-647A6925-2903-4E43-BD7E-68922E082563Q41460834-0559F38F-4360-4267-AD86-C484F9CED8A3Q41860837-E9A90480-62F5-47EC-8C9E-D920C4E97DB9Q42119477-1FF7970A-394B-417C-94C6-6813FE7BA547Q47106410-DD79662E-C3BF-4274-84DF-74FB6864DC5EQ47441361-B15214C4-E300-4538-84AC-53E3C0E8513AQ50883201-D4BB04CA-5C46-44BC-BF0D-7840D51163F4Q53197698-BB025C61-7B9B-4FE7-9B45-DCECBC90BC0DQ53642229-CA2384EA-7B4E-4616-B013-BF804656989EQ53661420-7D139E8E-06C8-4491-ACB3-D97150400F99Q57344642-6A6D595F-CFE9-436C-8996-79B2BCCA4DF1Q57344893-65FF0597-2D6B-42E0-B9A8-229FA77AFBA2Q57348044-00C61622-1DCA-49FF-BF2F-95E216350622
P2860
Minimizing the hydrodynamic size of quantum dots with multifunctional multidentate polymer ligands
description
article científic
@ca
article scientifique
@fr
articolo scientifico
@it
artigo científico
@pt
bilimsel makale
@tr
scientific article published on 05 August 2008
@en
vedecký článok
@sk
vetenskaplig artikel
@sv
videnskabelig artikel
@da
vědecký článek
@cs
name
Minimizing the hydrodynamic si ...... l multidentate polymer ligands
@en
Minimizing the hydrodynamic si ...... multidentate polymer ligands.
@nl
type
label
Minimizing the hydrodynamic si ...... l multidentate polymer ligands
@en
Minimizing the hydrodynamic si ...... multidentate polymer ligands.
@nl
prefLabel
Minimizing the hydrodynamic si ...... l multidentate polymer ligands
@en
Minimizing the hydrodynamic si ...... multidentate polymer ligands.
@nl
P2860
P356
P1476
Minimizing the hydrodynamic si ...... l multidentate polymer ligands
@en
P2093
Shuming Nie
P2860
P304
11278-11279
P356
10.1021/JA804306C
P407
P577
2008-08-05T00:00:00Z