In vivo molecular imaging of cancer with a quenching near-infrared fluorescent probe using conjugates of monoclonal antibodies and indocyanine green
about
A review of indocyanine green fluorescent imaging in surgeryClinical application of fluorescence imaging of liver cancer using indocyanine greenNeurosurgical confocal endomicroscopy: A review of contrast agents, confocal systems, and future imaging modalitiesNon-invasive in vivo imaging of tumor-associated CD133/promininOptical imaging probes in oncologyAdvances in fluorescent-image guided surgeryHS-133, a novel fluorescent phosphatidylinositol 3-kinase inhibitor as a potential imaging and anticancer agent for targeted therapyA Classic Near-Infrared Probe Indocyanine Green for Detecting Singlet OxygenHydrophobic fluorescent probes introduce artifacts into single molecule tracking experiments due to non-specific bindingSpectroscopic Photoacoustic Molecular Imaging of Breast Cancer using a B7-H3-targeted ICG Contrast AgentAnti-HER2 immunoliposomes for selective delivery of electron paramagnetic resonance imaging probes to HER2-overexpressing breast tumor cells.Antibody-based imaging of HER-2: moving into the clinic.Progress in molecular imaging in endoscopy and endomicroscopy for cancer imaging.New strategies for fluorescent probe design in medical diagnostic imaging.H-type dimer formation of fluorophores: a mechanism for activatable, in vivo optical molecular imagingNear infrared fluorescence-guided real-time endoscopic detection of peritoneal ovarian cancer nodules using intravenously injected indocyanine green.Minibody-indocyanine green based activatable optical imaging probes: the role of short polyethylene glycol linkersStructure-Inherent Targeting of Near-Infrared Fluorophores for Image-Guided SurgeryImmunotargeting of Integrin α6β4 for Single-Photon Emission Computed Tomography and Near-Infrared Fluorescence Imaging in a Pancreatic Cancer ModelIn vivo pentamodal tomographic imaging for small animals.Enhanced tumor treatment using biofunctional indocyanine green-containing nanostructure by intratumoral or intravenous injectionDevelopment and applications of photo-triggered theranostic agentsIn vivo photoacoustic therapy with cancer-targeted indocyanine green-containing nanoparticles.Non-invasive imaging of endothelial progenitor cells in tumor neovascularization using a novel dual-modality paramagnetic/near-infrared fluorescence probe.Optical imaging in vivo with a focus on paediatric disease: technical progress, current preclinical and clinical applications and future perspectivesIn vivo photoacoustic and fluorescence cystography using clinically relevant dual modal indocyanine green.Target-cancer-cell-specific activatable fluorescence imaging probes: rational design and in vivo applications.Photodynamic therapy for human hepatoma-cell-line tumors utilizing biliary excretion properties of indocyanine green.Current and future clinical applications for optical imaging of cancer: from intraoperative surgical guidance to cancer screeningImproved speciation characteristics of PEGylated indocyanine green-labeled Panitumumab: revisiting the solution and spectroscopic properties of a near-infrared emitting anti-HER1 antibody for optical imaging of cancer.Exogenous near-infrared fluorophores and their applications in cancer diagnosis: biological and clinical perspectives.Targeted, activatable, in vivo fluorescence imaging of prostate-specific membrane antigen (PSMA) positive tumors using the quenched humanized J591 antibody-indocyanine green (ICG) conjugate.Near-infrared molecular imaging of tumors via chemokine receptors CXCR4 and CXCR7.Indocyanine green targeted micelles with improved stability for near-infrared image-guided photothermal tumor therapy.Recent trends in antibody-based oncologic imagingFLIM-FRET for Cancer Applications.Inert coupling of IRDye800CW to monoclonal antibodies for clinical optical imaging of tumor targets.Near-infrared molecular probes for in vivo imaging.Peptide-Based Optical uPAR Imaging for Surgery: In Vivo Testing of ICG-Glu-Glu-AE105Dual imaging-guided photothermal/photodynamic therapy using micelles
P2860
Q21285140-D761444A-0FFD-491C-ACDB-233C9911744DQ26864620-CDA4C8AC-6A77-49F2-BBDD-731644BADBF2Q26991506-1EBE0492-6230-4CB5-96FD-806B57D307A1Q27438105-1E01AA68-BA4F-4366-9E23-44C0F21FE3D6Q28067824-8D05C1F4-7C2A-445B-9E1F-B6D73526801CQ28072620-18A27A8F-3863-45A1-A6D7-8EC8BDE8643DQ28383826-933B55CF-9692-448E-B236-23ECEF8134D7Q28389171-3BC83A4D-62DE-4F7F-AEF3-A8AA8E2EF1EEQ28533459-E891D20C-448C-43DE-A726-14DE585CD9C0Q30356039-12167F16-8366-4659-B56B-4CD8C6E16F5FQ30412654-9046F3B3-FBB1-4F83-8A4A-259B66947581Q30423880-12E21FDD-12A1-4459-9617-BB72002531F8Q30426514-23EEC39C-CD24-40C1-9CF8-6969B9606546Q30472058-755CFA52-2F5F-459E-A8A2-15C44072F7B7Q30490185-B1498A1D-4F55-4C0B-9048-6F5C6039E93CQ30502897-A671D2C9-464F-46DE-A84D-082BF24C37DEQ33636135-40C05C60-5D03-4CDC-9984-B9CAA2D9D557Q33760851-6FAD9890-4F0D-4958-88F6-4A8F7EBF62CEQ33793587-E7E5B540-A289-4894-9D98-AB11ED1457C3Q33824716-A488C4E0-09E0-4CAD-863F-DFA1C95EB80DQ34158431-B248EB06-51DF-454A-806E-5DFE438B43C7Q34349286-2BD64E2C-0F59-4FD4-9339-C557049DA623Q34410246-4AAF2382-DC7C-4B8C-9235-55FCC332DB8CQ34505528-6BF1B197-0301-4D73-970F-96FC6909C1DDQ34544842-7A62E131-D33C-43E9-A168-D468A4C1D227Q34554208-8292AAAC-34A8-4BC8-AA0E-6D8402801A36Q34579513-ED29AB6E-871E-4CAF-901F-653A34E3FF18Q34675821-093080F2-A4DA-4061-BEC2-AA999B3ACBD1Q34700347-1C3C799C-CDCD-42D4-83E4-FA250F9DCA9AQ34785833-2C4D62DF-B1C6-439C-8D1B-B3E38409287DQ34954961-C43F9B09-A1E8-445C-B261-D45A61C8C2EAQ35169090-6B13A40A-D773-423A-9062-594081B303FCQ35541948-D1688BAB-E715-4DD7-B449-B67DF20D63A8Q35566364-4A39FBD7-D49B-40A5-AA4A-2E758BC1E0B2Q35643425-52602948-E1CC-470F-9A71-9A9681DE7C34Q35646933-7B2E3F0E-DA8A-40BC-800D-EAC82C21F9B8Q35650596-806CD8ED-A3AB-48C7-A585-2EDE27219E07Q35906695-72A0D165-407F-4E09-B721-E3E28F91A68AQ35909379-5F464236-02A6-4A17-B158-D127198F0347Q36057256-EA1E0599-714B-4C2B-98A6-CDB4010098C0
P2860
In vivo molecular imaging of cancer with a quenching near-infrared fluorescent probe using conjugates of monoclonal antibodies and indocyanine green
description
2009 nî lūn-bûn
@nan
2009 թուականի Փետրուարին հրատարակուած գիտական յօդուած
@hyw
2009 թվականի փետրվարին հրատարակված գիտական հոդված
@hy
2009年の論文
@ja
2009年学术文章
@wuu
2009年学术文章
@zh-cn
2009年学术文章
@zh-hans
2009年学术文章
@zh-my
2009年学术文章
@zh-sg
2009年學術文章
@yue
name
In vivo molecular imaging of c ...... tibodies and indocyanine green
@ast
In vivo molecular imaging of c ...... tibodies and indocyanine green
@en
In vivo molecular imaging of c ...... tibodies and indocyanine green
@nl
type
label
In vivo molecular imaging of c ...... tibodies and indocyanine green
@ast
In vivo molecular imaging of c ...... tibodies and indocyanine green
@en
In vivo molecular imaging of c ...... tibodies and indocyanine green
@nl
prefLabel
In vivo molecular imaging of c ...... tibodies and indocyanine green
@ast
In vivo molecular imaging of c ...... tibodies and indocyanine green
@en
In vivo molecular imaging of c ...... tibodies and indocyanine green
@nl
P2093
P2860
P3181
P1433
P1476
In vivo molecular imaging of c ...... tibodies and indocyanine green
@en
P2093
Hisataka Kobayashi
Mikako Ogawa
Nobuyuki Kosaka
Peter L Choyke
P2860
P304
P3181
P356
10.1158/0008-5472.CAN-08-3116
P407
P577
2009-02-15T00:00:00Z