The use of fluorescent dyes and probes in surgical oncology.
about
A review of indocyanine green fluorescent imaging in surgeryNeurosurgical confocal endomicroscopy: A review of contrast agents, confocal systems, and future imaging modalitiesDual-labeling strategies for nuclear and fluorescence molecular imaging: a review and analysisAdvances in fluorescent-image guided surgeryNanoparticles for biomedical imaging: fundamentals of clinical translationExogenous Molecular Probes for Targeted Imaging in Cancer: Focus on Multi-modal Imaging.Self-interference fluorescence microscopy: three dimensional fluorescence imaging without depth scanning.Image-guided surgery using invisible near-infrared light: fundamentals of clinical translation.Inert coupling of IRDye800CW to monoclonal antibodies for clinical optical imaging of tumor targets.Molecular imaging needles: dual-modality optical coherence tomography and fluorescence imaging of labeled antibodies deep in tissue.Nanocolloidal albumin-IRDye 800CW: a near-infrared fluorescent tracer with optimal retention in the sentinel lymph node.Tri-modal microscope for head and neck tissue identificationSentinel node biopsy using indocyanine green in oral/oropharyngeal cancer.Morphological and phenotypical features of ovarian metastases in breast cancer patients.Probing the use of fluorescence spectroscopy as a novel diagnostic tool in patients with rheumatoid arthritis: applicability in the detection of secondary amyloidosis.Promiscuous tumor targeting phage proteins.Targeted zwitterionic near-infrared fluorophores for improved optical imagingNear-infrared lipophilic fluorophores for tracing tissue growth.Rapid Cancer Fluorescence Imaging Using A γ-Glutamyltranspeptidase-Specific Probe For Primary Lung CancerIdentification of cell-surface markers for detecting breast cancer cells in ovarian tissue.Photoacoustic imaging enhanced by indocyanine green-conjugated single-wall carbon nanotubesA Pretargeted Approach for the Multimodal PET/NIRF Imaging of Colorectal Cancer.Current trends and emerging future of indocyanine green usage in surgery and oncology: a literature review.Clinical imaging of tumor angiogenesis.Saccharide substituted zinc phthalocyanines: optical properties, interaction with bovine serum albumin and near infrared fluorescence imaging for sentinel lymph nodes.Application of infrared-based molecular imaging to a mouse model with head and neck cancer.Thoracoscopic color and fluorescence imaging system for sentinel lymph node mapping in porcine lung using indocyanine green-neomannosyl human serum albumin: intraoperative image-guided sentinel nodes navigation.Fast clearing RGD-based near-infrared fluorescent probes for in vivo tumor diagnosis.Chemoenzymatic strategy for the synthesis of site-specifically labeled immunoconjugates for multimodal PET and optical imaging.Biocompatible Near-Infrared Three-Dimensional Tracking System.Fluorescence-Guided Surgery.Inert coupling of IRDye800CW and zirconium-89 to monoclonal antibodies for single- or dual-mode fluorescence and PET imaging.Overcoming Autofluorescence: Long-Lifetime Infrared Nanoparticles for Time-Gated In Vivo Imaging.Comparison of near-infrared fluorescent deoxyglucose probes with different dyes for tumor diagnosis in vivoShortwave infrared fluorescence imaging with the clinically approved near-infrared dye indocyanine greenNanoprobes for intracellular and single cell surface-enhanced Raman spectroscopy (SERS)
P2860
Q21285140-155CD3E6-E202-4BB7-A6CF-D0841AC257F4Q26991506-F4B70089-5EF0-47E0-AB36-AAA8ACA4DD4EQ27027682-61CD2F3C-D6BD-4A7E-8552-B7E2702DDB51Q28072620-16E5EF06-7B1B-4F9B-B1E2-38B94BE92A2DQ28385644-CD628E8C-2E46-4F89-92C9-DA575BBA5FD0Q30472127-F3D18DFB-EC41-4B4F-9ABF-7DEBD493D061Q34330209-593A2B45-4791-4E1B-9B60-C7C5C666FF33Q35017959-D2681504-5F1B-4B58-9B92-EEFD571C9EC8Q35650596-AFC877AA-2BF7-4477-8D0D-3AFED078CDD6Q35681540-71FA23B5-F53B-4800-B057-46C7896FB15AQ36013532-BF6F5EDF-A0A1-4744-A68A-D62AD30682B7Q36032046-3A6C2745-885D-4578-84DC-22C667A49F14Q36071670-63A1B350-FE92-470D-811B-AC6CCE34A275Q36317398-140CEA51-B3B2-46A0-9155-F56B2A3EDFBAQ36576793-EDE38074-95E1-4977-A416-0F0F54CC2403Q36581309-B9FAF865-8392-4D84-B3C3-D8DB67739EDEQ36597658-CAACFE72-1908-4A2F-8052-4E78E668C3E8Q36660726-CA8ADC82-C1D7-48FE-8E88-62CCF10DEE64Q37028949-993BEA47-D487-4049-8C76-249D63AFB364Q37075568-CCC7E5C9-69E6-4551-A503-179FA4726368Q37139010-45537976-32F2-4113-808E-3B03F89119F0Q37469879-B4B7A950-75C7-403A-9628-9FE17B8CD390Q37864233-7BA9C966-EC8C-494E-8368-84905D46E938Q38059503-BE4FFDDD-8304-41CE-ACE5-42D38C9DEF4AQ38309548-40BD8E77-B79E-464A-90AC-A4DD87BB4271Q38837062-6616559C-98DF-4594-9F6A-D22484443126Q39300539-3B07B507-DB30-4D6F-83E8-10F762942761Q39339401-6C03F942-C18B-43BA-9B7B-923B4211AB75Q42556439-506B4614-10DB-4289-8FB8-6431AD40F6BEQ48575885-D9CCE832-16D4-478F-B77D-8B46A56ECD3BQ49472946-26B9C37F-401F-444F-995B-A86EBE72519CQ51039837-324C6FBF-2DA6-4432-9927-1D88C21B3553Q51778837-0BDF75C4-601A-460C-8C4A-FC34816D647DQ57273333-559610CC-269B-4147-81D8-004AA9F92048Q57352904-9D9EBDED-699F-4775-8C5E-2A06DE31707CQ58892566-1EC1BC96-FD93-411B-B939-32F843549116
P2860
The use of fluorescent dyes and probes in surgical oncology.
description
2009 nî lūn-bûn
@nan
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
2009年學術文章
@zh
2009年學術文章
@zh-hant
name
The use of fluorescent dyes and probes in surgical oncology.
@en
The use of fluorescent dyes and probes in surgical oncology.
@nl
type
label
The use of fluorescent dyes and probes in surgical oncology.
@en
The use of fluorescent dyes and probes in surgical oncology.
@nl
prefLabel
The use of fluorescent dyes and probes in surgical oncology.
@en
The use of fluorescent dyes and probes in surgical oncology.
@nl
P2093
P1476
The use of fluorescent dyes and probes in surgical oncology.
@en
P2093
E A Te Velde
Th Veerman
V Subramaniam
P356
10.1016/J.EJSO.2009.10.014
P577
2009-11-18T00:00:00Z