Integrated affinity capture, purification, and capillary electrophoresis microdevice for quantitative double-stranded DNA analysis.

A novel injection method is developed that utilizes a thermally switchable oligonucleotide affinity capture gel to mediate the concentration, purification, and injection of dsDNA for quantitative microchip capillary electrophoresis analysis. The affinity capture matrix consists of a 20 base acrydite modified oligonucleotide copolymerized into a 6% linear polyacrylamide gel that captures ssDNA or dsDNA analyte including PCR amplicons and synthetic oligonucleotides. Double stranded PCR amplicons with complementarity to the capture probe up to 81 bases from their 5' terminus are reproducibly captured via helix invasion. By integrating the oligo capture matrix directly with the CE separation channel, the electrophoretically mobilized target fragments are quantitatively captured and injected after thermal release for unbiased, efficient, and quantitative analysis. The capture process exhibits optimal efficiency at 44 degrees C and 100 V/cm with a 20 microM affinity capture probe (TM = 57.7 degrees C). A dsDNA titration assay with 20 bp fragments validated that dsDNA is captured at the same efficiency as ssDNA. Dilution studies with a duplex 20mer show that targets can be successfully captured and analyzed with a limit of detection of 1 pM from 250 nL of solution (approximately 150,000 fluorescent molecules). Simultaneous capture and injection of amplicons from E. coli K12 and M13mp18 using a mixture of two different capture probes demonstrates the feasibility of multiplex target capture. Unlike the traditional cross-injector, this method enables efficient capture and injection of dsDNA amplicons which will facilitate the quantitative analysis of products from integrated nanoliter-scale PCR reactors.

Multichannel reverse transcription-polymerase chain reaction microdevice for rapid gene expression and biomarker analysis.

A microdevice is developed for RNA analysis that integrates one-step reverse transcription and 30 cycles of PCR (RT-PCR) amplification with capillary electrophoresis (CE) separation and fluorescence detection of the amplicons. The four-layer glass-PDMS-glass-glass hybrid microdevice integrates microvalves, on-chip heaters and temperature sensors, nanoliter reaction chambers (380 nL), and 5-cm-long CE separation channels. The direct integration of these processes results in attomolar detection sensitivity (<11 template RNA molecules or approximately 0.1 cellular equiv) and rapid 45-min analysis, while minimizing sample waste and eliminating contamination. Size-based electrophoretic product analysis provides definitive amplicon-size verification and multiplex analysis. Multiplexed differential gene expression analysis is demonstrated on mdh and gyrB E. coli transcripts. RNA splice variant analysis of the RBBP8 gene is used to identify tumorigenic tissue. RT-PCR microdevice analysis of normal breast tissue RNA generates the expected 202-bp normal splice isoform; tumor breast tissue RNA samples generate a 151-bp amplicon signifying the presence of the tumorigenic splice variant. The ability to perform RNA transcript and splice variant biomarker analysis establishes our RT-PCR microdevice as a versatile gene expression platform.

Multichannel PCR-CE microdevice for genetic analysis.

We have developed a fully integrated multichannel polymerase chain reaction-capillary electrophoresis (PCR-CE) microdevice with nanoliter reactor volumes for highly parallel genetic analyses. Resistance temperature detectors and heaters made out of Ti/Pt are integrated on the microchip using a scalable radial design to provide precise temperature control of the four parallel PCR-CE reactor systems. Heating rates of >15 degrees C s(-1) and cooling rates of >10 degrees C s(-1) allow cycle times of 50 s and 30 complete PCR cycles in <27 min. PDMS membrane valves control and localize PCR reagents in the 380-nL reactors. By directly integrating PCR reactors with the CE separation system, efficient coupling of amplification with separation is achieved. The microdevice demonstrates good amplification uniformity and sensitivity down to 10 initial template copies in the 380-nL reactor (approximately 43 aM) with signal-to-noise ratio greater than 10. Parallel PCR-CE multiplex amplification and genetic analyses of four different samples with (1) both M13mp18 control template and E. coli K12 cells, (2) only M13mp18 template, (3) only E. coli K12 cells, and (4) negative control are completed in less than 30 min in a single run.