PCR is a common and often indispensable technique used in medical and biological research labs for
a variety of applications. Real-time quantitative PCR (RT-qPCR) has become a definitive technique for
quantitating differences in gene expression levels between samples. Yet, in spite of this importance, reliable
methods to quantitate nucleic acid amounts in a higher throughput remain elusive. In the following
paper, a unique design to quantify gene expression levels at the nanoscale in a continuous flow system is
presented. Fully automated, high-throughput, low volume amplification of deoxynucleotides (DNA) in a
droplet based microfluidic system is described. Unlike some conventional qPCR instrumentation that use
integrated fluidic circuits or plate arrays, the instrument performs qPCR in a continuous, micro-droplet
flowing process with droplet generation, distinctive reagent mixing, thermal cycling and optical detection
platforms all combined on one complete instrument. Detailed experimental profiling of reactions of less
than 300 nl total volume is achieved using the platform demonstrating the dynamic range to be 4 order
logs and consistent instrument sensitivity. Furthermore, reduced pipetting steps by as much as 90% and
a unique degree of hands-free automation makes the analytical possibilities for this instrumentation far
reaching. In conclusion, a discussion of the first demonstrations of this approach to perform novel, continuous
high-throughput biological screens is presented. The results generated from the instrument, when
compared with commercial instrumentation, demonstrate the instrument reliability and robustness to
carry out further studies of clinical significance with added throughput and economic benefits.
History
Publication
Biomolecular Detection and Quantification;4, pp. 22-32