Monpichar Srisa-Art

Quantitative detection of protein expression in single cells using droplet microfluidics

We demonstrate that single cells can be controllably compartmentalized within aqueous microdroplets; using such an approach we perform high-throughput screening by detecting the expression of a fluorescent protein in individual cells with simultaneous measurement of droplet size and cell occupancy.

Monitoring of real-time streptavidin-biotin binding kinetics using droplet microfluidics.

Rapid kinetic measurements are important in understanding chemical interactions especially for biological molecules. Herein, we present a droplet-based microfluidic platform to study streptavidin-biotin binding kinetics with millisecond time resolution. With integration of a confocal fluorescence detection system, individual droplets can be monitored and characterized online to extract kinetic information. Using this approach, binding kinetics between streptavidin and biotin were observed via fluorescence resonance energy transfer. The binding rate constant of streptavidin and biotin was found to be in a range of 3.0 x 10 (6)-4.5 x 10 (7) M (-1) s (-1).

Analysis of protein-protein interactions by using droplet-based microfluidics.

Every little drop: The KD values of angiogenin (ANG) interactions as shown by FRET analysis of thousands of pL‐sized droplets agree with data from bulk‐fluorescence polarization measurements. Importantly, the use of fluorophores does not affect the activity of ANG or the binding of anti‐ANG antibodies to ANG. Such an experimental platform could be applied to the high‐throughput analysis of protein–protein interactions.

Mapping of Fluidic Mixing in Microdroplets with 1 μs Time Resolution Using Fluorescence Lifetime Imaging

Microdroplets generated in microfluidic channels hold great promise for use as substrates in high-throughput chemical and biological analysis. These water-in-oil compartments can serve as isolated reaction vessels, and since they can be generated at rates in excess of 1 kHz, thousands of assays can be carried out quickly and reproducibly. Nevertheless, sampling the large amount of information generated from these platforms still remains a significant challenge. For example, considering the high droplet generation rates and velocities, reproducibility and micrometer resolution are challenging requirements that must be fulfilled. Herein we combine confocal fluorescence lifetime imaging microscopy with a statistical implementation that permits the analysis of mixing phenomena within microdroplets with a temporal resolution of 1 mus. Importantly, such exquisite resolution is only possible as a result of the large number of droplets sampled and their high structural reproducibility.

High-efficiency single-molecule detection within trapped aqueous microdroplets.

Aqueous droplets were used as a tool to confine a molecular population and enable highly efficient detection at the single-molecule level. Picoliter-sized aqueous droplets were generated using classical multiphase microfluidics with an aqueous stream containing the analyte under investigation and an oil carrier phase. The droplets were then localized and isolated in specially designed trapping areas within the microfluidic channel to provide a static environment for detection of the encapsulated molecules. We show that by continuously flowing the carrier oil phase while holding the aqueous stationary, we can significantly improve on measuring repeat single-molecule events. Further, we find that the flowing oil stream induces a circulation within the trapped droplets which is proportional to the volumetric flow velocity. This circulation phenomenon allows a given molecule to be detected multiple times during an experiment and can therefore be used for performing time-dependent single-molecule analysis.