In situ microarray fabrication and analysis using a microfluidic flow cell array integrated with surface plasmon resonance microscopy.

Surface Plasmon Resonance Microscopy (SPRM) is a promising label-free analytical tool for the real-time study of biomolecule interactions in a microarray format. However, flow cell design and microarray fabrication have hindered throughput and limited applications of SPRM. Here we report the integration of a microfluidic flow cell array (MFCA) with SPRM enabling in situ microarray fabrication and multichannel analysis of biomolecule probe-target interactions. We demonstrate the use of the MFCA for delivery of sample solutions with continuous flow in 24 channels in parallel for rapid microarray creation and binding analysis while using SPRM for real-time monitoring of these processes. Label-free measurement of antibody-antibody interactions demonstrates the capabilities of the integrated MFCA-SPRM system and establishes the first steps of the development of a high-throughput, label-free immunogenicity assay. After in situ probe antibody immobilization, target antibody binding was monitored in real time in 24 channels simultaneously. The limit of detection for this particular antibody pair is 80 ng/mL which is approximately 6 times lower than the industry recommended immunogenicity assay detection limit. The integrated MFCA-SPRM system is a powerful and versatile combination for a range of array-based analyses, including biomarker screening and drug discovery.

"Spot and hop": internal referencing for surface plasmon resonance imaging using a three-dimensional microfluidic flow cell array.

We have developed a novel referencing technique for surface plasmon resonance imaging systems referred to as "spot and hop." The technique enables internal referencing for individual flow cells in a parallel processing microfluidic network. Internal referencing provides the ability to correct for nonspecific binding and instrument drift, significantly improving data quality at each region of interest. The performance of a 48-flow-cell device was demonstrated through a series of studies, including "rise and fall" time, ligand preconcentration, ligand immobilization, analyte binding, and regeneration tests. Interfacing parallel processing fluidics with imaging systems will significantly expand the throughput and applications of array-based optical biosensors while retaining high data quality.

Improved continuous-flow print head for micro-array deposition.

Limitations in depositing ligands using conventional micro-array pin spotting have hindered the application of surface plasmon resonance imaging (SPRi) technology. To address these challenges we introduce a modification to our continuous-flow micro-spotting technology that improves ligand deposition. Using Flexchip protein A/G and neutravidin capturing surfaces, we demonstrate that our new microfluidic spotter requires 1000 times less concentrated antibodies and biotinylated ligands than is required for pin spotting. By varying the deposition flow rate, we show that the design of our tip overlay flow cell is efficient at delivering sample to the substrate surface. Finally, contact time studies show that it is possible to capture antibodies and biotinylated ligands at concentrations of less than 0.1 ug/ml and 100 pM, respectively. These improvements in spotting technology will help to expand the applications of SPRi systems in areas such as antibody screening, carbohydrate arrays, and biomarker detection.