Integrated Capillary Electrophoresis Devices with an Efficient Postcolumn Reactor in Planar Quartz and Glass Chips

Fluri, K.; Fitzpatrick, Glen; Chiem, Nghia; Harrison, David

doi:10.1021/ac9604090

Cited by 183 publications

(143 citation statements)

References 25 publications

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“…Structures on glass substrate are most commonly generated by standard photolithographic techniques. The basic manufacturing steps are the same as for silicon except the Cr/Au protective layer (the mask) representing a significant difference usually applied for glass [13,[22][23][24][25], where chrome is applied to enhance the adhesion of gold to the glass surface. Gold was found to be an efficient protective material for most glass-etching materials.…”

Section: Glass Wafermentioning

confidence: 99%

New advances in microchip fabrication for electrochromatography

Szekeres

Guttman

2005

Electrophoresis

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There is a great demand in separation technologies for faster and more effective analysis processes. Miniaturization is a suitable technique for satisfying this demand as reduction in size gives increased separation speed with higher efficiency. CEC is an electric-field-mediated separation technique where the liquid flow is generated by the electric field itself. The main advantage of using electric field over pressure for flow generation is the flat flow profile of the EOF; thus, CEC is one of the best candidates to construct a novel and high-efficiency microanalytical device. The aim of the present paper is to review the basic fabrication and bonding principles, as well as connection and system integration options for microfluidics-based electrochromatography. The physical structure and fluidic channel formation are critically evaluated, including glass microstructuring and fusion bonding. Recent developments in nanoflow measurements and the application of various flow control units are also extensively discussed.

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Section: Glass Wafermentioning

confidence: 99%

New advances in microchip fabrication for electrochromatography

Szekeres

Guttman

2005

Electrophoresis

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“…Therefore, this configuration is clearly unsuitable for an application that requires the injection of larger sample plugs to enhance detection sensitivity, which is largely dependent on the volume of sample solution. A more appropriate solution is to replace the cross-channel arrangement with double-T form [28]. This geometry allows for high-efficiency sample injections and geometric definition of sample plug size, irrespective of injector loading times or the applied injection potentials [28,29].…”

Section: Microchip Operationmentioning

confidence: 99%

“…A more appropriate solution is to replace the cross-channel arrangement with double-T form [28]. This geometry allows for high-efficiency sample injections and geometric definition of sample plug size, irrespective of injector loading times or the applied injection potentials [28,29]. The injected volume with the double-T-form injection system is determined by the double-T's length and always larger than that with the cross-injection system [25].…”

Section: Microchip Operationmentioning

confidence: 99%

Integration of a flow-type chemiluminescence detector on a glass electrophoresis chip

Lin

Uchiyama

et al. 2004

Talanta

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“…In analytical chemistry, a micro-total analysis system (µ-TAS) 1,2 and a lab-on-a-chip concept, 3 which is based on a micro-fluidic channel chip, have been developed as new tools. Microchip devices with miniaturized electrophoresis for high-speed analysis were applied to the determination of DNA fragments, [4][5][6] amino acids, [7][8][9] proteins, [10][11][12][13] and so forth. Moreover, integration of the analysis system is also an advantage of the microchip, for example, with cell analysis, [14][15][16] enzymatic reactions, [17][18][19] and biochemical reactions.…”

Section: Introductionmentioning

confidence: 99%

Fluorometric Determination of Sulfite and Nitrite in Aqueous Samples Using a Novel Detection Unit of a Microfluidic Device

et al. 2004

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On-chip fluorescence determination of sulfite and nitrite with N-(9-acridinyl)maleimide (NAM) and 2,3-diaminonaphthalene (DAN) has been developed using a novel fluorescence detection unit for microchip analysis. Usually, these fluorescence reagents are derivatized and detected separately in microchip analysis because different fluorescence wavelengths are emitted. The proposed fluorescence detection unit has optical fibers with no optical filter, and plural wavelengths of fluorescence were detected sensitively, even in the microchip. In this study, the simultaneous determination of sulfite and nitrite in environmental samples was performed with a polymer microchip analysis system. The calibration curves of sulfite and nitrite showed linear relations (R 2 = 0.998 (sulfite) and R 2 = 0.990 (nitrite)), and the relative standard deviations (RSD) for 4 runs were 2.1% (20 µM sulfite) and 1.3% (20 µM nitrite), respectively. The proposed method was applied to the recovery test of sulfite and nitrite in environmental samples.

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Integrated Capillary Electrophoresis Devices with an Efficient Postcolumn Reactor in Planar Quartz and Glass Chips

Cited by 183 publications

References 25 publications

New advances in microchip fabrication for electrochromatography

New advances in microchip fabrication for electrochromatography

Integration of a flow-type chemiluminescence detector on a glass electrophoresis chip

Fluorometric Determination of Sulfite and Nitrite in Aqueous Samples Using a Novel Detection Unit of a Microfluidic Device

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