about
Rational Design of a Colorimetric pH Sensor from a Soluble Retinoic Acid ChaperoneLuminescent dual sensors reveal extracellular pH-gradients and hypoxia on chronic wounds that disrupt epidermal repair.A simple and effective "capping" approach to readily tune the fluorescence of near-infrared cyaninesAn imaging method for oxygen distribution, respiration and photosynthesis at a microscopic level of resolution.Light-emitting hair follicles: studying skin regeneration with in vivo imaging.Evidence-based topical management of chronic wounds according to the T.I.M.E. principle.The Effect of pH on the Extracellular Matrix and Biofilms.pH-Sensitive polymeric micelle-based pH probe for detecting and imaging acidic biological environmentsFlexible pH-Sensing Hydrogel Fibers for Epidermal Applications.High-resolution Imaging of pH in Alkaline Sediments and Water Based on a New Rapid Response Fluorescent Planar Optode.Probe for the measurement of cell surface pH in vivo and ex vivo.A fluorescent colorimetric pH sensor and the influences of matrices on sensing performancesA protein-dye hybrid system as a narrow range tunable intracellular pH sensor.Biomarkers for infection: enzymes, microbes, and metabolites.Nanoparticle-based luminescent probes for intracellular sensing and imaging of pH.Biodegradable Microparticles for Simultaneous Detection of Counterfeit and Deteriorated Edible Products.Non-invasive Characterization of Immune Responses to Biomedical Implants.In cellulo protein labelling with Ru-conjugate for luminescence imaging and bioorthogonal photocatalysis.Proton-sensing G protein-coupled receptors as regulators of cell proliferation and migration during tumor growth and wound healing.Characterization of the Tumor Microenvironment and Tumor-Stroma Interaction by Non-invasive Preclinical ImagingCarbon dot-based inorganic-organic nanosystem for two-photon imaging and biosensing of pH variation in living cells and tissues.Design of a portable imager for near-infrared visualization of cutaneous wounds.A Co-Culture Model of Fibroblasts and Adipose Tissue-Derived Stem Cells Reveals New Insights into Impaired Wound Healing After Radiotherapy.Fluorescent pH-sensitive nanoparticles in an agarose matrix for imaging of bacterial growth and metabolism.Impact of a pH 5 Oil-in-Water Emulsion on Skin Surface pH.A sprayable luminescent pH sensor and its use for wound imaging in vivo.Low cost referenced luminescent imaging of oxygen and pH with a 2-CCD colour near infrared camera.Label-free detection of pH based on the i-motif using an aggregation-caused quenching strategy.Impact of age and body site on adult female skin surface pH.Localized intracellular pH measurement using a ratiometric photoinduced electron-transfer-based nanosensor.NHE1 expression at wound margins increases time-dependently during physiological healing.Fluorescent pH-Sensitive Nanoparticles in an Agarose Matrix for Imaging of Bacterial Growth and Metabolism
P2860
Q27680022-13B5306B-7D25-4111-B9E7-396AC4A71CDAQ30579232-718183D6-3D15-40C8-8C4F-9782D5A0723EQ33877912-0019EC28-8D4D-4E0F-BBB7-A6C8E001A28EQ34416705-9C195178-5B2A-4C9A-8A59-9F7EE113673BQ34703752-B1812505-229C-4952-A504-0B3BBB0E7385Q34815335-426ACF6B-2CBF-4A23-B2C5-E663F04449CFQ35802405-EF1369EA-A2D3-40AE-B396-D82B22D10274Q36223337-8AFFEFCC-B690-4234-A5B6-424525A38D44Q36723017-2CEFC74E-2044-4F64-AE40-E7E7F6D993D5Q36919186-BA5E8B27-A7F0-4E7D-A33E-4A49A4224593Q37126735-4DA688BC-4354-4CE2-8963-0F6D4B15CCC4Q37195812-6E9FBE1C-4413-4401-AE32-4E9228D4C505Q37467710-876D56A9-F566-4C5E-8207-FB4920984D20Q38465282-816E2386-66BF-45A5-80E0-E6549499E920Q38591300-1D49BF95-7975-4FA8-86D7-9A324DFC3A08Q38597787-DF3A2D4A-3675-4E26-91AF-9C4CA97300B3Q38599723-E62015DD-63AD-4EC3-B7E7-36025EFA527BQ38831089-576BB4A9-372D-41B8-A508-3BEB58166424Q38953330-372732D6-B02F-48E2-AA74-AA6C3744C377Q39135714-767F735E-D00A-4556-87C0-E182F97A4721Q39288460-FA53978F-D546-4D94-A0AD-C11D42C3587DQ40361601-662C24C4-ED48-40FD-BCD6-FEA513B11842Q42116707-A74887F4-09F5-447D-A1AD-6BC4CD92995CQ45367642-A0362B19-EBF7-47DE-A0B2-A7FD5FAF0033Q47621497-02831B13-34CB-430E-8240-8DEC12189F0CQ48545713-F6C5560C-6732-461A-ADC7-A68687D13389Q50426164-FDAF6AA1-A0F4-4740-8613-6832A7822028Q50927336-C37F986B-76FD-498B-B37A-DC4112304ABAQ51352014-9E010156-3AB9-4A4B-BED0-347B2102AE49Q51757256-EE7352F8-B5E3-4086-AE35-12E79BE50FF2Q52672123-50DB99C4-1907-452D-B479-1BED805AEE01Q56636915-E5A17566-1881-4BBF-AEA3-3C21A47A9DE8
P2860
description
2011 nî lūn-bûn
@nan
2011 թուականի Յունուարին հրատարակուած գիտական յօդուած
@hyw
2011 թվականի հունվարին հրատարակված գիտական հոդված
@hy
2011年の論文
@ja
2011年論文
@yue
2011年論文
@zh-hant
2011年論文
@zh-hk
2011年論文
@zh-mo
2011年論文
@zh-tw
2011年论文
@wuu
name
2D luminescence imaging of pH in vivo.
@ast
2D luminescence imaging of pH in vivo.
@en
type
label
2D luminescence imaging of pH in vivo.
@ast
2D luminescence imaging of pH in vivo.
@en
prefLabel
2D luminescence imaging of pH in vivo.
@ast
2D luminescence imaging of pH in vivo.
@en
P2093
P2860
P356
P1476
2D luminescence imaging of pH in vivo.
@en
P2093
Michael Landthaler
Otto S Wolfbeis
Philipp Babilas
Robert J Meier
Rolf-Markus Szeimies
Stephan Schreml
P2860
P304
P356
10.1073/PNAS.1006945108
P407
P577
2011-01-24T00:00:00Z