about
On the origin of life in the zinc world: 1. Photosynthesizing, porous edifices built of hydrothermally precipitated zinc sulfide as cradles of life on EarthNanotechnology, nanotoxicology, and neuroscienceMagnetic Nanoparticles in Cancer TheranosticsUltra-stable organic fluorophores for single-molecule researchNanoparticle-based monitoring of cell therapy.Fluorescent nanocrystals reveal regulated portals of entry into and between the cells of HydraGastrointestinal biodurability of engineered nanoparticles: Development of an in vitro assayCoherent optical spectroscopy in a biological semiconductor quantum dot-DNA hybrid systemThree-dimensional reconstruction of cell nuclei, internalized quantum dots and sites of lipid peroxidation.One at a time, live tracking of NGF axonal transport using quantum dotsVisualizing human prostate cancer cells in mouse skeleton using bioconjugated near-infrared fluorescent quantum dots.Synthesis and characterization of luminescent cadmium selenide/zinc selenide/zinc sulfide cholinomimetic quantum dots.Multidentate-protected colloidal gold nanocrystals: pH control of cooperative precipitation and surface layer shedding.Quantitative molecular profiling of biomarkers for pancreatic cancer with functionalized quantum dotsSemiautomated multiplexed quantum dot-based in situ hybridization and spectral deconvolutionNeuro-oncological applications of optical spectroscopy.Varied presentation of the Thomsen-Friedenreich disaccharide tumor-associated carbohydrate antigen on gold nanoparticlesSilicon nanoparticles: applications in cell biology and medicine.Clinical potential of quantum dotsEncapsulation and Functionalization of Nanoparticles in Crosslinked Resorcinarene Shells.Semiconductor quantum rods as single molecule fluorescent biological labels.Application of smart nanostructures in medicine.Nanotechnology and molecular cytogenetics: the future has not yet arrivedNanotechnology and the treatment of inner ear diseases.Pdots, a new type of nanoparticle, bind to mTHPC via their lipid modified surface and exhibit very high FRET efficiency between the core and the sensitizer.Labeling of mesenchymal stem cells by bioconjugated quantum dots.Time-resolved fluorescence immunoassay for C-reactive protein using colloidal semiconducting nanoparticles.QDs versus Alexa: reality of promising tools for immunocytochemistry.Intein-mediated site-specific conjugation of Quantum Dots to proteins in vivo.In vitro and In vivo Assessment of CdTe and CdHgTe Toxicity and Clearance.Nanobio applications of quantum dots in cancer: imaging, sensing, and targeting.Probing synaptic signaling with quantum dots.Volatile interface of biological oxidant and luminescent CdTe quantum dots: implications in nanodiagnostics.Two-Photon In Vivo Imaging with Porous Silicon Nanoparticles.Colloidal Quantum Nanostructures; Emerging Materials for Display Applications.Quantitative single particle tracking of NGF-receptor complexes: transport is bidirectional but biased by longer retrograde run lengths.Multiplex Photoluminescent Silicon Nanoprobe for Diagnostic Bioimaging and Intracellular Analysis.Gadolinium-labeled quantum dots for molecular magnetic resonance imaging: R1 versus R2 mappingThe Effect of Multidentate Biopolymer Based on Polyacrylamide Grafted onto Kappa-Carrageenan on the Spectrofluorometric Properties of Water-Soluble CdS Quantum Dots
P2860
Q21093195-E47F270B-4F26-4E56-9FC1-150A52240B09Q24650444-C3AA9967-102A-4556-ABEB-425D3BE8B293Q26784379-F5518D09-18AA-4D5A-9B59-FC673731313DQ26858810-7EFA9C8D-DB47-4509-B3F5-BACD504F0B8FQ27000646-BC93BEC4-A3D7-490D-8497-8CB579EAADB4Q27336062-7B343201-7DF3-4619-9214-683C31347701Q30431391-777D3F7A-A488-46FA-9A00-587569080285Q30469542-E422082A-2F5D-4600-83F9-F12301906742Q30478265-2265FBAE-E3DB-4D59-B7A5-BAD255B7F937Q30479997-DB9BC61A-C279-4DA8-8482-FAFDF294D3F8Q34010389-4AE14C60-AF61-4912-AC49-7922714F7D7CQ34320705-E4D46151-28B7-4120-941B-321B9B00E7C7Q34975567-E49100C7-E748-4830-B62F-7E428D5C5028Q35965742-6475C22C-0A57-4DF5-AEE1-12F1CCC7CF42Q36471600-B09D205D-5AE7-4940-B378-02F2632A32DBQ36478652-F3D623FA-A1D7-4BBE-9651-315B45614C8CQ36853557-94581F5C-7F69-4ED2-9534-F1AA411A697AQ36920337-5C869C45-77DC-43A6-9591-053D48523472Q37101245-C2D4071A-6701-4B0F-AB32-DEA9FB613626Q37147471-2C0F4CB6-8A32-411F-8A63-8B9697451828Q37699412-9CC56575-F827-409E-8EB1-2DC84A5FF858Q37793084-7A9690CC-CF80-4B46-B8FF-E6E8D6616B15Q37960003-C74FD3DA-23FC-4FA9-BA8D-AC403B15E44AQ38264388-8387B516-9073-4107-A8AA-9D1678DDB5CEQ39020425-97A9534C-3198-49F1-A35A-8C63F8C55BA3Q39978227-A1EF217D-9F4F-4A84-AF06-9E5EAF5C847EQ40182097-24155883-4365-4C5D-8152-0B79B47E4A57Q41884176-634283D3-CD27-4345-B5F3-6F971C039F55Q41910476-D3309F4A-2F4D-4A0D-B7DE-2B5F547EA913Q42576170-ABE612F0-356B-46AC-B074-997FCEBE20CBQ42794091-CB53424B-B1F7-4C36-8894-6A25D79A17FBQ43177895-97889025-1233-47BA-9D93-B9FF22BB8DF1Q46090168-F84B5247-4F1B-4943-B79E-6E4A27EFE9EBQ47553122-A17590F9-0D5F-40D3-AA7C-05BBC8D43A24Q47916074-5B9620B8-9A35-40BC-92B7-3C72DB4CC337Q48909674-61E23232-2B56-4AE7-9630-755639A7EEF0Q55026935-E463C560-D0CB-4905-BDD7-1905D62386B4Q57185629-ADB50953-1A1A-4937-8679-3C4773953E59Q58688882-A7210E32-53E1-4EE7-A4EA-9FF98138AFF5
P2860
description
2005 nî lūn-bûn
@nan
2005年の論文
@ja
2005年論文
@yue
2005年論文
@zh-hant
2005年論文
@zh-hk
2005年論文
@zh-mo
2005年論文
@zh-tw
2005年论文
@wuu
2005年论文
@zh
2005年论文
@zh-cn
name
Semiconductor nanocrystals for biological imaging.
@ast
Semiconductor nanocrystals for biological imaging.
@en
type
label
Semiconductor nanocrystals for biological imaging.
@ast
Semiconductor nanocrystals for biological imaging.
@en
prefLabel
Semiconductor nanocrystals for biological imaging.
@ast
Semiconductor nanocrystals for biological imaging.
@en
P2093
P1476
Semiconductor nanocrystals for biological imaging.
@en
P2093
Carolyn Larabell
P304
P356
10.1016/J.CONB.2005.08.004
P577
2005-10-01T00:00:00Z