Model based design of a microfluidic mixer driven by induced charge electroosmosis

Mixing chemical or biological samples with reagents for chemical analysis is one of the most time consuming operations on microfluidic platforms. This is primarily due to the low rate of diffusive transport in liquid systems. Additionally, much research has focused on detection, rather than sample p...

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Veröffentlicht in:	Lab on a chip 2008-01, Vol.8 (4), p.565-572
Hauptverfasser:	Harnett, Cindy K, Templeton, Jeremy, Dunphy-Guzman, Katherine A, Senousy, Yehya M, Kanouff, Michael P
Format:	Artikel
Sprache:	eng
Schlagworte:	Biomarkers - analysis Biomarkers - chemistry Diffusion Electronics Electroosmosis - instrumentation Electroosmosis - methods Electrophysiology - instrumentation Electrophysiology - methods Microfluidics - instrumentation Microfluidics - methods Models, Theoretical Static Electricity
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creator	Harnett, Cindy K Templeton, Jeremy Dunphy-Guzman, Katherine A Senousy, Yehya M Kanouff, Michael P
description	Mixing chemical or biological samples with reagents for chemical analysis is one of the most time consuming operations on microfluidic platforms. This is primarily due to the low rate of diffusive transport in liquid systems. Additionally, much research has focused on detection, rather than sample preparation. In response, we describe a mixer for microfluidic sample preparation based on the electrokinetic phenomenon of induced-charge-electroosmosis (ICEO). ICEO creates microvortices within a fluidic channel by application of alternating current (AC) electric fields. The microvortices are driven by electrostatic forces acting on the ionic charge induced by the field near polarizable materials. By enabling mixing to be turned on or off within a channel of fixed volume, these electronically controlled mixers prevent sample dilution-a common problem with other strategies. A three-dimensional model based on the finite volume method was developed to calculate the electric field, fluid flow, and mass transport in a multi-species liquid. After preliminary experiments, the model was used to rapidly prototype a wide range of designs. A new microfabrication process was developed for devices with vertical sidewalls having conductive metal coatings and embedded electrodes. Mixing experiments were carried out in the devices and the results were compared to the model.
doi_str_mv	10.1039/b717416k
format	Article
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source	MEDLINE; Royal Society Of Chemistry Journals 2008-; Alma/SFX Local Collection
subjects	Biomarkers - analysis Biomarkers - chemistry Diffusion Electronics Electroosmosis - instrumentation Electroosmosis - methods Electrophysiology - instrumentation Electrophysiology - methods Microfluidics - instrumentation Microfluidics - methods Models, Theoretical Static Electricity
title	Model based design of a microfluidic mixer driven by induced charge electroosmosis
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