Activatable rotor for quantifying lysosomal viscosity in living cells.
about
d-PET-controlled "off-on" Polarity-sensitive Probes for Reporting Local Hydrophilicity within LysosomesQuantitatively mapping cellular viscosity with detailed organelle information via a designed PET fluorescent probe.Multifunctional Benzothiadiazole-Based Small Molecules Displaying Solvatochromism and Sensing Properties toward Nitroarenes, Anions, and Cations.Visualization of endogenous and exogenous hydrogen peroxide using a lysosome-targetable fluorescent probe.BODIPY-BODIPY dyad: assessing the potential as a viscometer for molecular and ionic liquids.Discerning the Chemistry in Individual Organelles with Small-Molecule Fluorescent Probes.Unusual Fluorescent Responses of Morpholine-functionalized Fluorescent Probes to pH via Manipulation of BODIPY's HOMO and LUMO Energy Orbitals for Intracellular pH DetectionA Simple BODIPY-Based Viscosity Probe for Imaging of Cellular Viscosity in Live Cells.Imaging tumor microscopic viscosity in vivo using molecular rotors.Exploring viscosity, polarity and temperature sensitivity of BODIPY-based molecular rotors.Ratiometric fluorescence imaging of cellular polarity: decrease in mitochondrial polarity in cancer cells.Theranostic iridium(III) complexes as one- and two-photon phosphorescent trackers to monitor autophagic lysosomes.A multifunctional nanomicelle for real-time targeted imaging and precise near-infrared cancer therapy.Motion-induced change in emission (MICE) for developing fluorescent probes.Tuning the Sensitivity of Fluorescent Porphyrin Dimers to Viscosity and Temperature.A Molecular Rotor that Measures Dynamic Changes of Lipid Bilayer Viscosity Caused by Oxidative Stress.An efficient ratiometric fluorescent probe for tracking dynamic changes in lysosomal pH.Ultrathin two-dimensional porous organic nanosheets with molecular rotors for chemical sensing.A Deoxyuridine-Based Far-Red Emitting Viscosity Sensor.Off-on-off fluorescent chemosensor for pH measurement with a terbium(iii) complex based on a tripodal salicylic-acid derivative.A Lysosome-Compatible Near-Infrared Fluorescent Probe for Targeted Monitoring of Nitric Oxide.Molecular Viscosity Sensors with Two Rotators for Optimizing the Fluorescence Intensity-Contrast Trade-Off.Luminescent Probes for Sensitive Detection of pH Changes in Live Cells through Two Near-Infrared Luminescence Channels.A two-photon fluorescent probe for real-time monitoring of autophagy by ultrasensitive detection of the change in lysosomal polarity.Assembly of BODIPY-carbazole dyes with liposomes to fabricate fluorescent nanoparticles for lysosomal bioimaging in living cells.Live Cell Imaging of Viscosity in 3D Tumour Cell Models.One-pot synthesis and properties of well-defined butadiynylene-BODIPY oligomers.Amphiphilic BODIPY derivatives: the solvophobic effect on their photophysical properties and bioimaging in living cells.Suppression of Kasha's rule as a mechanism for fluorescent molecular rotors and aggregation-induced emission.Pyrrolic molecular rotors acting as viscosity sensors with high fluorescence contrast.A Lysosome-Targeting AIEgen for Autophagy Visualization.An acidic pH independent piperazine-TPE AIEgen as a unique bioprobe for lysosome tracing.A lysosome-targeted fluorescent chemodosimeter for monitoring endogenous and exogenous hydrogen sulfide by in vivo imaging.BODIPY-based fluorescent thermometer as a lysosome-targetable probe: how the oligo(ethylene glycols) compete photoinduced electron transfer.BODIPY-based oligo(ethylene glycol) dendrons as fluorescence thermometers: when thermoresponsiveness meets intramolecular electron/charge transfer.Fluorescent Probes for Sensitive and Selective Detection of pH Changes in Live Cells in Visible and Near-infrared Channels.A molecular rotor for measuring viscosity in plasma membranes of live cells.Near-infrared fluorescent probes based on piperazine-functionalized BODIPY dyes for sensitive detection of lysosomal pHFluorescent Probes Based on π-Conjugation Modulation between Hemicyanine and Coumarin Moieties for Ratiometric Detection of pH Changes in Live Cells with Visible and Near-infrared ChannelsA novel NBD-based pH “on–off” fluorescent probe equipped with the N-phenylpiperazine group for lysosome imaging
P2860
Q28821423-CD06C365-FBD0-4559-9DB6-F1FF5C02D45AQ33794784-39AAF420-A719-4EA3-9472-6E833588FCBAQ34794783-7095749F-9B5E-4B5A-8130-1BBF68F1B40DQ35086653-0FACA163-F1F0-4051-A6E8-97A8E4B1158FQ35239734-616D88C1-555F-4328-BA48-3FE4340F6651Q36115905-E138F2D2-2B61-49F0-9754-0DA0E544941BQ37183480-E360A8BF-42BD-455D-BCC0-34E1F5ABF94DQ37288905-869DDA09-09D4-4078-91DF-B697AC2C5D24Q37612355-8AFA383A-A1FD-4F0A-9668-7038E0E04992Q38674267-41E9D7AD-036B-4AF6-A2CF-23756082092DQ38921749-ED1DEF70-1358-4EF1-BA71-5C7E65ECB71EQ38954296-97DE0607-9810-46E9-A3FF-EB68C4E20CFDQ38973416-BEE34A50-7689-41CE-B649-19883F3B579AQ39425538-04DC9C00-C3E0-4A3B-91F5-C3A9E73235CCQ41552259-F428200B-5C2D-474A-A0C7-CD9D73754F33Q41673876-95EC3854-9A1F-4C6D-A84C-DB0EAD43E75AQ41917359-AA2378A3-C58D-4966-A8D9-729C627E1966Q42630139-04094CA7-FA76-41D9-B820-8DFE155E64E1Q42810219-2091B320-E074-41C8-AA94-574B60CFE884Q43938273-38F47D02-63ED-4E4A-A15D-1BDCECF4A41CQ47445991-15398587-A118-45B7-82E3-04ED5745DB7DQ47593009-A4337024-534C-421A-B35A-3F353CE48659Q47954349-2ADAC420-0412-40B6-A9C6-DB7041236B6BQ48187903-63F77BB5-5D1C-417B-AE4E-8D16381F1438Q48295856-F941FC03-2DCD-4E40-A7F0-E24519BE46A2Q50100703-D49D7BB7-2CEE-4965-A894-CADC67A0E2E6Q50209312-51005C1F-C5C0-4575-8E69-7E1528D4036EQ50226672-938C6AC3-B1DD-495B-B5B0-3ED338BE2DEBQ50999957-7DF0B23F-81A7-4BC0-BBF0-38C976A53E64Q51106271-585F0E05-9788-44D6-A542-54D6EB172345Q51599220-4A58BC79-EE48-4141-BA32-0D8DB88AC294Q52641554-51C4F54A-DA99-4A4D-B064-D972C3007E0FQ52779493-9A21F1CA-EB75-48F4-87F2-3DE9404541FBQ53347982-ABDC2912-6C51-43DE-98B1-475F363B6CA9Q53407301-8C789C59-F067-4A35-8703-111073760DE7Q53833384-12E25F85-88E2-44F5-9AFC-C875E67215EDQ54551434-716258B7-3099-44A4-8C99-33049A01356DQ57204408-6EBE99E1-A839-40E7-9621-AF8AECD1216FQ57496179-24385D8D-DFAE-4E1A-991C-A9DC34A4DEA6Q58860203-F5DDC680-61D5-4F38-BC3B-D6E17702C07E
P2860
Activatable rotor for quantifying lysosomal viscosity in living cells.
description
2013 nî lūn-bûn
@nan
2013 թուականի Փետրուարին հրատարակուած գիտական յօդուած
@hyw
2013 թվականի փետրվարին հրատարակված գիտական հոդված
@hy
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
name
Activatable rotor for quantifying lysosomal viscosity in living cells.
@ast
Activatable rotor for quantifying lysosomal viscosity in living cells.
@en
type
label
Activatable rotor for quantifying lysosomal viscosity in living cells.
@ast
Activatable rotor for quantifying lysosomal viscosity in living cells.
@en
prefLabel
Activatable rotor for quantifying lysosomal viscosity in living cells.
@ast
Activatable rotor for quantifying lysosomal viscosity in living cells.
@en
P2093
P356
P1476
Activatable rotor for quantifying lysosomal viscosity in living cells.
@en
P2093
Liezheng Deng
Wenming Tian
P304
P356
10.1021/JA311688G
P407
P577
2013-02-19T00:00:00Z