A laminated, flex structure for electronic transport and hybridization of DNA.

We have developed the first prototypes of a three-dimensional, electrophoretically driven microlaboratory for the analysis of proteins and DNA. By selecting the appropriate spacing and geometrical configuration, oligonucleotides were transported, in a controlled, rapid fashion, by electrophoresis in free-space. Transport efficiencies over 2 mm distances exceeded 70%. Electrodes of similar design were combined with an electronically addressed DNA hybridization chip to form a fully electrophoretic microlaboratory. In this instance, gold-plated copper electrodes were patterned on a 2 mil thick polyimide substrate. This polyimide layer was stiffened with 20 mil of polyimide to provide support for flip-chip bonding of our standard 100-site Nanochip. This composite structure illustrated three-dimensional transport of target oligonucleotides, through a via in the polyimide, along a series of electrodes and onto the diagnostic chip. Upon reaching the diagnostic chip, electronic hybridization was performed for a competitive reverse dot blot assay. The electronic assay showed a specific to nonspecific ratio in excess of 20:1. These results suggested that this type of structure might be of practical consequence with the development of a microlaboratory for biowarfare applications.

Electric manipulation of bioparticles and macromolecules on microfabricated electrodes.

Bioparticle separation, bioparticle enrichment, and electric field-mediated immune detection were carried out on microfabricated semiconductor chips utilizing ac and dc electric fields. Microscale separation on a chip surface having an active area of approximately 16 mm2 was demonstrated for a mixture of Bacillus globigii spores and Escherichia coli bacteria. Dielectrophoretic enrichment was performed by collecting target bioparticles from a flow stream in flow cells of 47.5 microL, achieving a 20-fold increase in the concentration of E. coli bacteria from a diluted sample, a 28-fold enrichment for peripheral blood mononuclear cells from red blood cells, and a 30-fold increase in white blood cells from diluted whole blood. The ability to manipulate and collect bioparticles and macromolecules at microfabricated electrodes with ac and dc fields was further illustrated in electric field-mediated immunoassays for analyzing the biological identities of E. coli bacteria and B. globigii spores. According to these results, the electric methods for manipulating bioparticles present themselves as viable techniques for novel biomedical applications in sample preparations and biochemical assays on microelectrode arrays.

Detection of biological toxins on an active electronic microchip.

An electric-field-driven assay for fluorescein-labeled staphylococcal enterotoxin B and cholera toxin B was developed on an active electronic microchip. An array of microlocations was transformed into an immunoassay array by electronically biasing electrodes at each microlocation to attract biotinylated capture antibodies. The electric field generated on the array directed the transport, concentration, and binding of biotinylated capture antibodies to streptavidin-coated microlocations. Subsequently, solutions of fluorescein-labeled staphylococcal enterotoxin B and fluorescein-labeled cholera toxin B were electronically addressed to the assay sites by an applied electric field. Each toxin was specifically bound to microlocations containing the appropriate capture antibody with little nonspecific binding to assay sites lacking the appropriate capture antibody. It was possible to detect both toxins from a mixture in a single electronic addressing step; detection was accomplished after a 1-min application of the electric field followed by washing. The ability to perform a rapid, electric field-mediated immunoassay for multiple analytes may provide an advantage over existing approaches.