Electrochemistry-based real-time PCR on a microchip.

The development of handheld instruments for point-of-care DNA analysis can potentially contribute to the medical diagnostics and environmental monitoring for decentralized applications. In this work, we demonstrate the implementation of a recently developed electrochemical real-time polymerase chain reaction (ERT-PCR) technique on a silicon-glass microchip for simultaneous DNA amplification and detection. This on-chip ERT-PCR process requires the extension of an oligonucleotide in both solution and at solid phases and intermittent electrochemical signal measurement in the presence of all the PCR reagents. Several important parameters, related to the surface passivation and electrochemical scanning of working electrodes, were investigated. It was found that the ERT-PCR's onset thermal cycle ( approximately 3-5), where the analytical signal begins to be distinguishable from the background, is much lower than that of the fluorescence-based counterparts for high template DNA situations (3 x 10(6) copies/microL). By carefully controlling the concentrations of the immobilized probe and the enzyme polymerase, improvements have been made in obtaining a meaningful electrochemical signal using a lower initial template concentration. This ERT-PCR technique on a microchip platform holds significant promise for rapid DNA detection for point-of-care testing applications.

Electrochemical real-time polymerase chain reaction.

In this work, we report the first electrochemistry-based real-time polymerase chain reaction technique for sequence-specific nucleic acid detection. This new technique builds upon the advantages of the well-established fluorescence-based counterpart, such as short assay time (simultaneous target DNA amplification and detection). In addition, this electrochemical approach could employ simple and miniaturizable instrumentation compared to the bulky and expensive optics required in the fluorescence-based schemes. We have demonstrated a proof-of-concept experiment showing that the utilization of solid-phase extension of the electrode surface-immobilized capture probe with Fc-dUTP during PCR resulted in the accumulation of the redox marker on the transducer surface. This new technique can be applied to a microfabricated PCR electrochemical device for point-of-care diagnostics as well as on-site environmental monitoring and biowarfare agent detection.