Javier Farinas

Comparison of on-chip and off-chip microfluidic kinase assay formats.

Kinases represent an important class of targets for pharmaceutical drug development. Microfluidic devices capable of running kinase assays with either an on-chip or an off-chip enzymatic reaction have been developed. For the on-chip assay, reagent addition, mixing, enzymatic reaction, and electrophoretic separation and detection of substrate and product all take place in the channels of the microfluidic chip. For the off-chip assay, the reaction takes place in a microtiter plate, whereas the electrophoretic separation and detection of substrate and product take place in the channels of the chip. To probe differences between the on-chip and off-chip assays, a panel of commercially available kinase inhibitors was assayed at 10 microM against cyclic AMP-dependent protein kinase A, glycogen synthase kinase 3beta, mitogen- and stress-activated protein kinase, and Akt1 using both the off-chip and on-chip assays. Good correlation was observed between inhibition measured by the two methods, with most of the differences in measured inhibition being attributed to compound solubility and enzyme concentration effects. Microfluidic devices represent an attractive platform for kinase assays due to high data quality and the possibility of on-chip assay integration, leading to reagent and labor savings.

Nucleic Acid Amplification of Individual Molecules in a Microfluidic Device

A microfluidic device was developed that enabled rapid polymerase chain reaction (PCR) analysis of individual DNA molecules. The device combined a means for accessing samples serially from a microtiter plate, channels for assembling eight parallel PCR reactions, and integrated resistive heaters for rapid thermocycling (>5 degrees C/s heating, >7 degrees C/s cooling) of samples as they flowed continuously through PCR channels. Amplification was monitored by fluorescence detection of Taqman probes. The long, narrow channels (10 microm x 180 microm x 40 mm) allowed sufficient separation between neighboring DNA templates to enable amplification of discreet DNA molecules. The functionality of the device was demonstrated by reproducibly amplifying a 2D6.6 CYP450 template and distinguishing between wild-type and mutant sequences using Taqman probes. A comparison of the rate of individual amplification events to the expected Poisson distribution confirmed that the device could reliably analyze individual DNA molecules. This work establishes the feasibility of rapid, single-molecule interrogation of nucleic acids.

Single-molecule enzymology based on the principle of the Millikan oil drop experiment.

The ability to monitor the progress of single-molecule enzyme reactions is often limited by the need to use fluorogenic substrates. A method based on the principle of the Millikan oil drop experiment was developed to monitor the change in charge of substrates bound to a nanoparticle and offers a means of detecting single-enzyme reactions without fluorescence detection. As a proof of principle of the ability to monitor reactions that result in a change in substrate charge, polymerization on a single DNA template was detected. A custom oligonucleotide was synthesized that allowed for the attachment of single DNA templates to gold nanoparticles with a single polymer tether. The nanoparticles were then tethered to the surface of a microfluidic channel where the positions of the nanoparticles, subjected to an oscillating electric field, were monitored using dark field microscopy. With short averaging times, the signal-to-noise level was low enough to discriminate changes in charge of less than 1.2%. Polymerization of a long DNA template demonstrated the ability to use the system to monitor single-molecule enzymatic activity. Finally, nanoparticle surfaces were modified with thiolated moieties to reduce and/or shield the number of unproductive charges and allow for improved sensitivity.

Label-free DNA sequencing using Millikan detection

A label-free method for DNA sequencing based on the principle of the Millikan oil drop experiment was developed. This sequencing-by-synthesis approach sensed increases in bead charge as nucleotides were added by a polymerase to DNA templates attached to beads. The balance between an electrical force, which was dependent on the number of nucleotide charges on a bead, and opposing hydrodynamic drag and restoring tether forces resulted in a bead velocity that was a function of the number of nucleotides attached to the bead. The velocity of beads tethered via a polymer to a microfluidic channel and subjected to an oscillating electric field was measured using dark-field microscopy and used to determine how many nucleotides were incorporated during each sequencing-by-synthesis cycle. Increases in bead velocity of approximately 1% were reliably detected during DNA polymerization, allowing for sequencing of short DNA templates. The method could lead to a low-cost, high-throughput sequencing platform that could enable routine sequencing in medical applications.