Microfluidic platforms for lab-on-a-chip applications
Identifieur interne : 000D40 ( Main/Exploration ); précédent : 000D39; suivant : 000D41Microfluidic platforms for lab-on-a-chip applications
Auteurs : Stefan Haeberle [Allemagne] ; Roland Zengerle [Allemagne]Source :
- Lab on a Chip [ 1473-0197 ] ; 2007.
English descriptors
- Entity :
- org : Agilent Technologies, Canada, Israel and Korea, Duke University, Fluidigm Corporation, IMIT—Institute for Micromachining and Information Technology, IMTEK, Laboratory for MEMS Applications, Department of Microsystems Engineering, MicroNano Technologies for Biosciences, NanoTech, Nanotech, Raindance Technologies, Switzerland Miniaturisation, UCLA, University of Augsburg, Germany, University of California, University of California, Los Angeles, University of Chicago, University of Freiburg.
- pers : Achim Wixforth, An, Critical, George Whiteside, Ismagilov, Michael G. Pollack, Roland Zengerleab, Stefan Haeberlea, Stephen Quake, Weitz.
- place : America, Europe, Germany, Montreux, Sweden, Switzerland.
- Teeft :
- Acoustic, Actuation, Actuation fleece, Actuator, Agilent technology, Anal, Assay, Assay result, Blood sample, Capillary channel, Capillary electrophoresis, Capillary force, Capillary valve, Carrier fluid, Carrier phase, Centrifugal, Centrifugal force, Centrifugal microfluidic platform, Centrifugal platform, Channel wall, Chem, Complete drainage, Contact angle, Control channel, Crystallization, Crystallization chamber, Daub, Detection zone, Diagnostic application, Different application, Disposable, Droplet, Droplet generation, Droplet movement, Ducree, Elastomer, Electric field, Electrode, Electrokinetic, Electrokinetic platform, Electroosmotic flow, Electrowetting, Ewod, Ewod platform, Fabrication technology, Fleece, Fluid channel, Fluid transport, Fluidic, Fluidic unit operation, Free scalable, Heij, Immunoassay, Incubation time, International conference, Ismagilov, Lateral flow assay, Life science, Liquid droplet, Liquid flow, Liquid plug, Liquid portion, Liquid property, Liquid stream, Liquid volume, Many different type, Manz, Microfluidic, Microfluidic channel, Microfluidic large scale integration, Microfluidic platform, Microfluidic realization, Microfluidics, Nozzle, Nozzle chamber, Other hand, Pdms, Phys, Precipitant, Pressure pulse, Protein crystallization, Protein crystallization assay, Protein solution, Readout, Reagent, Research community, Royal society, Sample liquid, Segmented flow, Separation channel, Shear force, Single droplet, Steinert, Surface acoustic wave, Test strip, Test strip platform, Tice, Topspot1, Topspot1 technology, Unit operation, Valve, Wide range, Zengerle.
Abstract
We review microfluidic platforms that enable the miniaturization, integration and automation of biochemical assays. Nowadays nearly an unmanageable variety of alternative approaches exists that can do this in principle. Here we focus on those kinds of platforms only that allow performance of a set of microfluidic functions—defined as microfluidic unit operations—which can be easily combined within a well defined and consistent fabrication technology to implement application specific biochemical assays in an easy, flexible and ideally monolithically way. The microfluidic platforms discussed in the following are capillary test strips, also known as lateral flow assays, the “microfluidic large scale integration” approach, centrifugal microfluidics, the electrokinetic platform, pressure driven droplet based microfluidics, electrowetting based microfluidics, SAW driven microfluidics and, last but not least, “free scalable non-contact dispensing”. The microfluidic unit operations discussed within those platforms are fluid transport, metering, mixing, switching, incubation, separation, droplet formation, droplet splitting, nL and pL dispensing, and detection.
Url:
DOI: 10.1039/b706364b
Affiliations:
Links toward previous steps (curation, corpus...)
- to stream Istex, to step Corpus: 002998
- to stream Istex, to step Curation: 002764
- to stream Istex, to step Checkpoint: 000C75
- to stream Main, to step Merge: 000D47
- to stream Main, to step Curation: 000D40
Le document en format XML
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Pollack</term><term>Roland Zengerleab</term><term>Stefan Haeberlea</term><term>Stephen Quake</term><term>Weitz</term></keywords><keywords scheme="Entity" type="place" xml:lang="en"><term>America</term><term>Europe</term><term>Germany</term><term>Montreux</term><term>Sweden</term><term>Switzerland</term></keywords><keywords scheme="Teeft" xml:lang="en"><term>Acoustic</term><term>Actuation</term><term>Actuation fleece</term><term>Actuator</term><term>Agilent technology</term><term>Anal</term><term>Assay</term><term>Assay result</term><term>Blood sample</term><term>Capillary channel</term><term>Capillary electrophoresis</term><term>Capillary force</term><term>Capillary valve</term><term>Carrier fluid</term><term>Carrier phase</term><term>Centrifugal</term><term>Centrifugal force</term><term>Centrifugal microfluidic platform</term><term>Centrifugal platform</term><term>Channel wall</term><term>Chem</term><term>Complete drainage</term><term>Contact angle</term><term>Control channel</term><term>Crystallization</term><term>Crystallization chamber</term><term>Daub</term><term>Detection zone</term><term>Diagnostic application</term><term>Different application</term><term>Disposable</term><term>Droplet</term><term>Droplet generation</term><term>Droplet movement</term><term>Ducree</term><term>Elastomer</term><term>Electric field</term><term>Electrode</term><term>Electrokinetic</term><term>Electrokinetic platform</term><term>Electroosmotic flow</term><term>Electrowetting</term><term>Ewod</term><term>Ewod platform</term><term>Fabrication technology</term><term>Fleece</term><term>Fluid channel</term><term>Fluid transport</term><term>Fluidic</term><term>Fluidic unit operation</term><term>Free scalable</term><term>Heij</term><term>Immunoassay</term><term>Incubation time</term><term>International conference</term><term>Ismagilov</term><term>Lateral flow assay</term><term>Life science</term><term>Liquid droplet</term><term>Liquid flow</term><term>Liquid plug</term><term>Liquid portion</term><term>Liquid property</term><term>Liquid stream</term><term>Liquid volume</term><term>Many different type</term><term>Manz</term><term>Microfluidic</term><term>Microfluidic channel</term><term>Microfluidic large scale integration</term><term>Microfluidic platform</term><term>Microfluidic realization</term><term>Microfluidics</term><term>Nozzle</term><term>Nozzle chamber</term><term>Other hand</term><term>Pdms</term><term>Phys</term><term>Precipitant</term><term>Pressure pulse</term><term>Protein crystallization</term><term>Protein crystallization assay</term><term>Protein solution</term><term>Readout</term><term>Reagent</term><term>Research community</term><term>Royal society</term><term>Sample liquid</term><term>Segmented flow</term><term>Separation channel</term><term>Shear force</term><term>Single droplet</term><term>Steinert</term><term>Surface acoustic wave</term><term>Test strip</term><term>Test strip platform</term><term>Tice</term><term>Topspot1</term><term>Topspot1 technology</term><term>Unit operation</term><term>Valve</term><term>Wide range</term><term>Zengerle</term></keywords></textClass><langUsage><language ident="en">en</language></langUsage></profileDesc></teiHeader><front><div type="abstract">We review microfluidic platforms that enable the miniaturization, integration and automation of biochemical assays. Nowadays nearly an unmanageable variety of alternative approaches exists that can do this in principle. Here we focus on those kinds of platforms only that allow performance of a set of microfluidic functions—defined as microfluidic unit operations—which can be easily combined within a well defined and consistent fabrication technology to implement application specific biochemical assays in an easy, flexible and ideally monolithically way. The microfluidic platforms discussed in the following are capillary test strips, also known as lateral flow assays, the “microfluidic large scale integration” approach, centrifugal microfluidics, the electrokinetic platform, pressure driven droplet based microfluidics, electrowetting based microfluidics, SAW driven microfluidics and, last but not least, “free scalable non-contact dispensing”. The microfluidic unit operations discussed within those platforms are fluid transport, metering, mixing, switching, incubation, separation, droplet formation, droplet splitting, nL and pL dispensing, and detection.</div></front></TEI><affiliations><list><country><li>Allemagne</li></country><region><li>Bade-Wurtemberg</li><li>District de Fribourg-en-Brisgau</li></region><settlement><li>Fribourg-en-Brisgau</li></settlement></list><tree><country name="Allemagne"><noRegion><name sortKey="Haeberle, Stefan" sort="Haeberle, Stefan" uniqKey="Haeberle S" first="Stefan" last="Haeberle">Stefan Haeberle</name></noRegion><name sortKey="Zengerle, Roland" sort="Zengerle, Roland" uniqKey="Zengerle R" first="Roland" last="Zengerle">Roland Zengerle</name><name sortKey="Zengerle, Roland" sort="Zengerle, Roland" uniqKey="Zengerle R" first="Roland" last="Zengerle">Roland Zengerle</name><name sortKey="Zengerle, Roland" sort="Zengerle, Roland" uniqKey="Zengerle R" first="Roland" last="Zengerle">Roland Zengerle</name></country></tree></affiliations></record>Pour manipuler ce document sous Unix (Dilib)
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