Strategy for dual-analyte luciferin imaging: in vivo bioluminescence detection of hydrogen peroxide and caspase activity in a murine model of acute inflammation.
about
Click chemistry in complex mixtures: bioorthogonal bioconjugationDetection of superoxide anion and hydrogen peroxide production by cellular NADPH oxidasesBeyond D-luciferin: expanding the scope of bioluminescence imaging in vivoBiosensors with built-in biomolecular logic gates for practical applicationsBioorthogonal cyclization-mediated in situ self-assembly of small-molecule probes for imaging caspase activity in vivoOpening a Gateway for Chemiluminescence Cell Imaging: Distinctive Methodology for Design of Bright Chemiluminescent Dioxetane Probes.In situ activation and monitoring of the evolution of the intracellular caspase familyBoronate-based fluorescent probes: imaging hydrogen peroxide in living systems.A biocompatible "split luciferin" reaction and its application for non-invasive bioluminescent imaging of protease activity in living animalsRecent advances in hydrogen peroxide imaging for biological applicationsA miniaturized device for bioluminescence analysis of caspase-3/7 activity in a single apoptotic cell.Fiat Luc: Bioluminescence Imaging Reveals In Vivo Viral Replication Dynamics.Small Molecule Active Site Directed Tools for Studying Human CaspasesLuciferin Amides Enable in Vivo Bioluminescence Detection of Endogenous Fatty Acid Amide Hydrolase Activity.[(11)C]Ascorbic and [(11)C]dehydroascorbic acid, an endogenous redox pair for sensing reactive oxygen species using positron emission tomographyIn vivo bioluminescence imaging reveals copper deficiency in a murine model of nonalcoholic fatty liver disease.In vivo targeting of hydrogen peroxide by activatable cell-penetrating peptides.A biocompatible, highly efficient click reaction and its applications."AND" luminescent "reactive" molecular logic gates: a gateway to multi-analyte bioimaging and biosensing.Bioresponsive probes for molecular imaging: concepts and in vivo applications.Chemical approaches to discovery and study of sources and targets of hydrogen peroxide redox signaling through NADPH oxidase proteins.Intracellular synthesis of d-aminoluciferin for bioluminescence generation.A fast-responsive mitochondria-targeted fluorescent probe detecting endogenous hypochlorite in living RAW 264.7 cells and nude mouse."Double gating"--a concept for enzyme-responsive imaging probes aiming at high tissue specificity.A boronate-caged [¹⁸F]FLT probe for hydrogen peroxide detection using positron emission tomography.Chemiluminescent detection of cell apoptosis enzyme by gold nanoparticle-based resonance energy transfer assay.A Single Fluorescent Probe to Visualize Hydrogen Sulfide and Hydrogen Polysulfides with Different Fluorescence Signals.On the use of peroxy-caged luciferin (PCL-1) probe for bioluminescent detection of inflammatory oxidants in vitro and in vivo - Identification of reaction intermediates and oxidant-specific minor products.A simple bioluminescent method for measuring D-amino acid oxidase activitySite-selective protein immobilization through 2-cyanobenzothiazole-cysteine condensation.A H2O2-Responsive Theranostic Probe for Endothelial Injury Imaging and Protection.Design of modular dual enzyme-responsive peptides.In vivo bioluminescence imaging of labile iron accumulation in a murine model of Acinetobacter baumannii infection.Physical, Chemical, and Biological Structures based on ROS-Sensitive Moieties that are Able to Respond to Oxidative Microenvironments.Development of a Sensitive Bioluminogenic Probe for Imaging Highly Reactive Oxygen Species in Living Rats.Click beetle luciferase mutant and near infrared naphthyl-luciferins for improved bioluminescence imaging.Synthetic Biomarker Design by Using Analyte-Responsive Acetaminophen.Peroxidase-Mimicking Nanozyme with Enhanced Activity and High Stability Based on Metal-Support Interactions.Dual enzyme-responsive "turn-on" fluorescence sensing systems based on in situ formation of 7-hydroxy-2-iminocoumarin scaffolds.Cysteine-Mediated Intracellular Building of Luciferin to Enhance Probe Retention and Fluorescence Turn-On.
P2860
Q26828895-0097B957-1991-4F84-9B4E-AFBC90991C70Q27022012-B06A2A7B-D246-43E0-B61B-EF3D6DEB4279Q27026277-9419BD43-3D77-433C-958F-8C4938DCCFEAQ28081299-954C6101-CAC7-44CF-852D-6E7293787EB6Q30578692-C90046AF-176D-4CA8-9AEE-23C1715B2A03Q33612449-A7643663-028A-4C57-8022-9D21AAAEBE76Q33851560-29DF5583-D760-4251-AC91-5E351D92046FQ33895637-A67D878C-2BB0-431E-B8A8-777A0C5CDCC1Q34448294-641DDBAE-B98F-4643-904C-907B7B123307Q34515147-AD94F0B1-F4CB-47A9-AB38-4B3BE3C80D1BQ35191845-E7CC6E21-666F-46CC-A1C1-4DCA726CF4D4Q35769197-55C23CB5-7DEB-4F73-9EA8-A4819D50B9E1Q35836079-14F7130D-2DF5-4541-9912-C4218FFB7163Q35866385-9192C7A6-7FE2-408B-B9DD-270517F19BB1Q36862062-A6BBC660-44EE-43AC-B226-53F0F64F6491Q37514940-7C2E5128-6933-44B7-A1A5-3D1C50409FB1Q37593509-D5866C16-568B-47EF-8F79-297594B5C4B2Q38171259-63798AD7-62B2-4791-9766-9B3CA34859B6Q38287109-E3A0B58A-48E2-407D-B427-CB180B0AE49CQ38420827-8480196C-DEB6-4A4B-9528-B0DCDFB12BB3Q38512709-4D43D848-13CC-47BA-BAE6-6E1043013F39Q38746583-8B57104D-8352-4455-BC2B-2AEFEA7D19ABQ38930883-E10ADABC-BAA3-4281-A5DE-83FC7F364CA6Q38946918-5390C2EB-BDC3-4BCC-9CC5-D4D3746A7224Q38948479-0C3F2FA1-E451-4530-A40B-368959E7CDFCQ39028715-E34EC866-A25D-49C2-A1FD-75C4CFE2B8B4Q39319907-09B0F81F-A7A7-4B76-82BD-6C47A121B709Q41642064-1FAA7CE1-7B7D-4C6B-B911-07D9CE34F32BQ41904350-6BF58262-462F-43C8-B9DA-DF4CB72E6ED7Q42233689-0722DB09-D5DE-4D87-9CDA-35F587986657Q45843246-5F132165-460B-4443-9971-FB7E2C6E0CA5Q45993690-E9527F3A-AE97-4209-8473-BD3CC3B6AAEDQ46249324-047116F5-43CE-4ADE-9790-35F74EBEA272Q46547606-862FD811-0701-486B-923C-CD2C96577C6AQ46653017-B569C831-DE95-4E7D-AF1C-A8F772D55192Q47873378-6C567C8A-0B85-432F-A6D9-F5FD116B32AFQ48822089-C6AA21ED-C71F-4264-900B-1D65792AA6BDQ49390170-E252954B-D7AD-4B43-9ED3-758F902A0A71Q50941963-978E0482-3B2B-4F35-AE3A-CED3FD77CEF7Q50961486-DD244464-53B6-4F30-8896-64E0889926F1
P2860
Strategy for dual-analyte luciferin imaging: in vivo bioluminescence detection of hydrogen peroxide and caspase activity in a murine model of acute inflammation.
description
2013 nî lūn-bûn
@nan
2013年の論文
@ja
2013年論文
@yue
2013年論文
@zh-hant
2013年論文
@zh-hk
2013年論文
@zh-mo
2013年論文
@zh-tw
2013年论文
@wuu
2013年论文
@zh
2013年论文
@zh-cn
name
Strategy for dual-analyte luci ...... e model of acute inflammation.
@ast
Strategy for dual-analyte luci ...... e model of acute inflammation.
@en
type
label
Strategy for dual-analyte luci ...... e model of acute inflammation.
@ast
Strategy for dual-analyte luci ...... e model of acute inflammation.
@en
prefLabel
Strategy for dual-analyte luci ...... e model of acute inflammation.
@ast
Strategy for dual-analyte luci ...... e model of acute inflammation.
@en
P2860
P356
P1476
Strategy for dual-analyte luci ...... e model of acute inflammation.
@en
P2093
Christopher J Chang
Genevieve C Van de Bittner
P2860
P304
P356
10.1021/JA309078T
P407
P577
2013-01-25T00:00:00Z