about
Fiber-Optic Chemical Sensors and Fiber-Optic Bio-SensorsIntegrating Nanostructured Artificial Receptors with Whispering Gallery Mode Optical Microresonators via Inorganic Molecular Imprinting TechniquesFiber loop ringdown - a time-domain sensing technique for multi-function fiber optic sensor platforms: current status and design perspectives.Photoluminescent Metal-Organic Frameworks for Gas SensingA Flexible Optical pH Sensor Based on Polysulfone Membranes Coated with pH-Responsive Polyaniline NanofibersWireless microstimulators for neural prosthetics.Nanostructured Gas Sensors for Health Care: An Overview.Sol-Gel Thin Films for Plasmonic Gas Sensors.A high sensitivity and wide dynamic range fiber-optic sensor for low-concentration VOC gas detection.CMOS Imaging of Pin-Printed Xerogel-Based Luminescent Sensor Microarrays.Imprinting of Molecular Recognition Sites on Nanostructures and Its Applications in Chemosensors.Laser spectroscopy for atmospheric and environmental sensingA New Crosslinkable Oxygen Sensor Covalently Bonded into Poly(2-hydroxyethyl methacrylate)-CO-Polyacrylamide Thin Film for Dissolved Oxygen Sensing.Naked eye detection of multiple tumor-related mRNAs from patients with photonic-crystal micropattern supported dual-modal upconversion bioprobesData processing for image-based chemical sensors: unsupervised region of interest selection and background noise compensation.Nanostructured oxygen sensor--using micelles to incorporate a hydrophobic platinum porphyrinMiniaturized optical chemosensor for flow-based assaysA polymeric waveguide resonant mirror (RM) device for detection in microfluidic flow cells.Micro flow reactor chips with integrated luminescent chemosensors for spatially resolved on-line chemical reaction monitoring.Hybrid micro-/nanogels for optical sensing and intracellular imaging.Bioconjugation strategies for microtoroidal optical resonatorsLUMOS--A Sensitive and Reliable Optode System for Measuring Dissolved Oxygen in the Nanomolar Range.Assembly, growth and nonlinear thermo-optical properties of nitropeptides.Direct-Dispense Polymeric Waveguides Platform for Optical Chemical Sensors.Polarization and symmetry of electronic transitions in long fluorescence lifetime triangulenium dyes.Diurnal Variability in Chlorophyll-a, Carotenoids, CDOM and SO₄(2-) Intensity of Offshore Seawater Detected by an Underwater Fluorescence-Raman Spectral System.Optical detection in microfluidic systems.Nanoparticle strategies for enhancing the sensitivity of fluorescence-based biochips.Optical chemical sensors based on hybrid organic-inorganic sol-gel nanoreactors.Hybrid materials for optics and photonics.Nanogold-based sensing of environmental toxins: excitement and challenges.Optical oxygen sensors for applications in microfluidic cell culture.Optical probes and techniques for O2 measurement in live cells and tissue.Fluorescence-based biosensors.Indicators for optical oxygen sensors.Recent progress in optical chemical sensors.Biological detection by optical oxygen sensing.A gold nanorod-based localized surface plasmon resonance platform for the detection of environmentally toxic metal ions.Luminescent films for chemo- and biosensing.Fluorescent nanoparticles for the accurate detection of drug delivery.
P2860
Q26782073-C3B42DA3-1064-40C0-A318-F4F1B167BC2CQ28383274-E95425F2-F053-4F78-B26F-2B628C2C5084Q28731600-F5C13E67-9F97-4421-AE64-5117AE328ACEQ28821692-5417EFCD-5424-4E86-9282-7A58891199B9Q28828184-F3A4C572-83E5-42F8-BE90-09127ED66C14Q30379442-5DFB910B-2329-472D-AF9F-81E329DB1F78Q30401010-95EC5E35-E360-41BE-BEEB-D0DF90470B9EQ30404453-15B81E2E-F1FD-4DDC-972C-CDC08F990BB8Q30420350-6894F6EC-0677-43BC-8900-8049822BDAFCQ30443762-45630DCD-12E1-456A-AE41-1C1EE268B01AQ30448225-61BBF7F0-B6DA-4742-B01E-3CC9CE9D5D48Q30470803-56D53862-DC5A-4FAE-AE37-94274624DC54Q33750053-DC51A1BD-6C91-4E05-9C0B-5239A7D0314AQ33763486-D16CD7A0-733E-458B-91E7-AFB638D37B69Q34068303-F3BCF8BB-2E50-4F5C-92F9-203BD222D94AQ34211853-C413B43F-97BF-4B39-A63E-0783ADC6F697Q34477222-1534DC24-7AF0-4303-8E8A-0200CD5CEA22Q34675590-368F8062-EBCD-4C21-B0AC-FD39388996C7Q34967438-21221D4D-DEF8-4649-9F27-DC0007A2A7F1Q35547382-F6F79DD6-510C-4858-BD00-C14B9CAAFE7EQ35593452-8EF1A8EF-AADE-436D-8B1E-E028A50B9846Q35647578-B8FF40FF-F028-40BF-BB69-5E08FA275D45Q35659780-E69A730F-FC5A-4B7E-B8C2-C35D1D2CE8A8Q36200845-04819F5A-68C0-4739-8DFB-CBF4F5B2649AQ36691880-DD79B9AA-9193-4D92-AB50-5A2C248253CBQ37145513-E5D1B724-C0AE-477E-B04D-E51242D7AA97Q37515153-195100AB-703D-4B44-AB3F-7A61F0B19166Q37575472-FEBAA5E2-3318-4342-BD7A-27D66A5BD8F3Q37823367-B733435E-24BA-45D9-8B6F-96C2107A720FQ37826629-B11D3726-2EAB-43CB-AB05-02AC878B1B08Q37855701-E7D5CD9D-5093-4A7D-B94D-14B7B2EADDA3Q37967749-965CA505-7866-49E4-A65D-523984CA0529Q37976259-C43F4882-FC75-4038-A7E7-61A346DDAE6AQ38008977-221E34A3-3EF5-49DC-9B02-93DF97081DFDQ38066218-1726D1E0-5C16-4430-983A-E984631431F4Q38084854-82E53E4C-6367-4A59-AF3D-1E7DFA2423ADQ38115186-CB293C4D-0BF3-4590-AF9C-D8D42BD2AF7CQ38367511-897B1CFB-92A5-47C6-B27C-A00922D4B55FQ38545658-485BB996-5D56-4A41-A74C-B42232B12744Q38570366-626F9713-0DB1-47D4-9849-3AF898698381
P2860
description
article científic
@ca
article scientifique
@fr
articolo scientifico
@it
artigo científico
@pt
bilimsel makale
@tr
scientific article published on 30 January 2008
@en
vedecký článok
@sk
vetenskaplig artikel
@sv
videnskabelig artikel
@da
vědecký článek
@cs
name
Optical chemical sensors.
@en
Optical chemical sensors.
@nl
type
label
Optical chemical sensors.
@en
Optical chemical sensors.
@nl
prefLabel
Optical chemical sensors.
@en
Optical chemical sensors.
@nl
P356
P1433
P1476
Optical chemical sensors.
@en
P2093
Brian D MacCraith
Conor S Burke
P304
P356
10.1021/CR068102G
P577
2008-01-30T00:00:00Z