Johan Roeraade scite author profile

In this report we describe a new way of fabricating integrated microfluidic elements in glass. By employing a matrix of underpinning posts and a thin wall, surrounding etched flow channels, an efficient sealing of glass chips substrates to thin cover glass can be accomplished. The use of this arrangement enables the overlay sheath of glass to hermetically close the flow channel by fusion bonding while avoiding problems with void or crack formation that are due to dust particles, non-planarity and differences in thermal coefficient of expansion. As an example a structure with a thin cover glass, useful for studying phenomena in capillary electrophoresis utilizing large numerical aperture microscope lenses, was fabricated.

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Protein microarrays for diagnostic assays

Hartmann

et al. 2008

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Protein microarray technology has enormous potential for in vitro diagnostics (IVD). Miniaturized parallelized immunoassays are perfectly suited to generating a maximum of diagnostically relevant information from minute amounts of sample whilst only requiring small amounts of reagent. Protein microarrays have become well-established research tools in basic and applied research and the first products are already on the market. This article reviews the current state of protein microarrays and discusses developments and future demands relating to protein arrays in their role as multiplexed immunoassays in the field of diagnostics.

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Continuous Segmented-Flow Polymerase Chain Reaction for High-Throughput Miniaturized DNA Amplification

2002

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A continuous segmented-flow method for sequential DNA amplification is described in order to provide a basis for high-throughput genetic analysis. The approach allows an immediate distinction between amplified and nonamplified products. A mixture of sample and reagents are loaded in the form of small segments one after another in a 15-m-long narrow-bore Teflon tube, coiled such as to be repeatedly exposed to three different temperature zones. After having passed the heated zones, the samples are mixed with an intercalating dye by flow injection and sequentially detected on-line by laser-induced fluorescence. The aqueous samples travel as separate segments in a continuous flow of an immiscible, organic liquid. Perfluorodecalin was shown to be particularly suitable due to its hydrophobicity and inert properties. To reduce carryover between samples, an intermediate water plug between two consecutive samples was required. Selected regions from human genomic DNA were successfully amplified in 300-nL volumes after 30 passes through the heated zones. The total reaction time was approximately 45 min, and the detection interval between individual samples was 1 min. Automation and the possibility to further reduce sample volumes, as well as to employ many reaction columns simultaneously, should provide a platform for an extremely high throughput.

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Automated Microdroplet Platform for Sample Manipulation and Polymerase Chain Reaction

et al. 2006

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We present a fully automated system performing continuous sampling, reagent mixing, and polymerase chain reaction (PCR) in microdroplets transported in immiscible oil. Sample preparation and analysis are totally automated, using an original injection method from a modified 96-well plate layered with three superimposed liquid layers and in-capillary laser-induced fluorescence endpoint detection. The process is continuous, allowing sample droplets to be carried uninterruptedly into the reaction zone while new drops are aspirated from the sample plate. Reproducible amplification, negligible cross-contamination, and detection of low sample concentrations were demonstrated on numerous consecutive sample drops. The system, which opens the route to strong reagents and labor savings in high-throughput applications, was validated on the clinically relevant quantification of progesterone receptor gene expression in human breast cancer cell lines.

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Johan Roeraade

Method for fabrication of microfluidic systems in glass

Protein microarrays for diagnostic assays

Continuous Segmented-Flow Polymerase Chain Reaction for High-Throughput Miniaturized DNA Amplification

Automated Microdroplet Platform for Sample Manipulation and Polymerase Chain Reaction

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