Laser-induced fluorescence detector for capillary-based isoelectric immunoblot assay.

We describe a whole-capillary, multicolor laser-induced fluorescence scanner for microfluidic protein analysis systems. Separation of proteins is achieved by isoelectric focusing in a short length of fused-silica capillary after which the resolved proteins are immobilized to the capillary wall using photochemistry. The capillary is then evacuated, and fluorescently labeled antibodies are flowed through the capillary to bind to the immobilized proteins. This technique provides high sensitivity, the ability to spatially resolve and quantify proteins, and provides the opportunity for complete automation. Results obtained by fluorescence detection are compared to those obtained by chemiluminescence while offering enhanced resolution and signal stability.

Isoelectric focusing technology quantifies protein signaling in 25 cells.

A previously undescribed isoelectric focusing technology allows cell signaling to be quantitatively assessed in <25 cells. High-resolution capillary isoelectric focusing allows isoforms and individual phosphorylation forms to be resolved, often to baseline, in a 400-nl capillary. Key to the method is photochemical capture of the resolved protein forms. Once immobilized, the proteins can be probed with specific antibodies flowed through the capillary. Antibodies bound to their targets are detected by chemiluminescence. Because chemiluminescent substrates are flowed through the capillary during detection, localized substrate depletion is overcome, giving excellent linearity of response across several orders of magnitude. By analyzing pan-specific antibody signals from individual resolved forms of a protein, each of these can be quantified, without the problems associated with using multiple antibodies with different binding avidities to detect individual protein forms.