Results 261 to 270 of about 132,158 (308)
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Emerging paper microfluidic devices
The Analyst, 2019Paper has unique advantages over other materials, including low cost, flexibility, porosity, and self-driven liquid pumping, thus making it widely used in various fields in biology, chemistry, physics and materials science.
Bingbing Gao +4 more
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Microfluidic Devices for Bioapplications
Small, 2010AbstractHarnessing the ability to precisely and reproducibly actuate fluids and manipulate bioparticles such as DNA, cells, and molecules at the microscale, microfluidics is a powerful tool that is currently revolutionizing chemical and biological analysis by replicating laboratory bench‐top technology on a miniature chip‐scale device, thus allowing ...
Yeo, Leslie Y. +3 more
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2023
A microfluidic device (1) comprising: a fluidic inlet (14) and a fluidic outlet (16), and a plurality of interconnected fluidic channels (31, 32), fluidically coupling the fluidic inlet (14) to the fluidic outlet (16), wherein a net nominal flow direction (4) of each of the plurality of interconnected fluidic channels (31, 32) is substantially parallel,
Desmet, Gert +3 more
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A microfluidic device (1) comprising: a fluidic inlet (14) and a fluidic outlet (16), and a plurality of interconnected fluidic channels (31, 32), fluidically coupling the fluidic inlet (14) to the fluidic outlet (16), wherein a net nominal flow direction (4) of each of the plurality of interconnected fluidic channels (31, 32) is substantially parallel,
Desmet, Gert +3 more
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ELECTROPHORESIS, 2009
AbstractIEF is one of the most powerful and prevalent techniques used in separation sciences. The power of IEF comes from the fact that it not only separates analytes based on their pI but also focuses them into highly resolved bands. In line with the miniaturization trend spurring the analytical community, the past decade has yielded a wealth of ...
Greg J, Sommer, Anson V, Hatch
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AbstractIEF is one of the most powerful and prevalent techniques used in separation sciences. The power of IEF comes from the fact that it not only separates analytes based on their pI but also focuses them into highly resolved bands. In line with the miniaturization trend spurring the analytical community, the past decade has yielded a wealth of ...
Greg J, Sommer, Anson V, Hatch
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Microfluidic ion-sensing devices
Analytica Chimica Acta, 2008Quantitative determinations of ions in a variety of media have been performed traditionally via one of three approaches: optical instrumental methods (e.g., atomic absorption, and inductively-coupled plasma-optical emission or mass spectrometry), "wet" methods, or ion-selective sensors.
R Daniel, Johnson +3 more
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Bioanalysis in microfluidic devices
Journal of Chromatography A, 2002Microfabricated bioanalytical devices (also referred to as laboratory-on-a-chip or micro-TAS) offer highly efficient platforms for simultaneous analysis of a large number of biologically important molecules, possessing great potential for genome, proteome and metabolome studies.
Julia, Khandurina, András, Guttman
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Polyimide-based microfluidic devices
Lab on a Chip, 2001This paper describes the development of polyimide-based microfluidic devices. A layer transfer and lamination technique is used to fabricate flexible microfluidic channels in various shapes and with a wide range of dimensions. High bond strengths can be achieved by cure cycle adaptation and surface treatment of the polyimide layers prior to bonding ...
S, Metz, R, Holzer, P, Renaud
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Integrated microfluidic devices
Analytica Chimica Acta, 2004“With the fundamentals of microscale flow and species transport well developed, the recent trend in microfluidics has been to work towards the development of integrated devices which incorporate multiple fluidic, electronic and mechanical components or chemical processes onto a single chip sized substrate.
David Erickson, Dongqing Li
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2020
Functional diversification is expected to drive the growth of hardware computing beyond the end of Moore’s law. Medical application is expected to be a system driver of such diversification. Microfluidic technologies enable miniaturization of laboratory-based biochemical protocols.
Mohammed Shayan +3 more
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Functional diversification is expected to drive the growth of hardware computing beyond the end of Moore’s law. Medical application is expected to be a system driver of such diversification. Microfluidic technologies enable miniaturization of laboratory-based biochemical protocols.
Mohammed Shayan +3 more
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Electrochemical paper‐based microfluidic devices
ELECTROPHORESIS, 2015Self‐pumping porous microfluidic devices have attracted significant interest because of their low cost and broad applicability in point‐of‐care and low resource settings. One limitation of many of the devices is sensitivity and selectivity for detection.
Jaclyn, Adkins +2 more
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