Abstract: A screening system and method are described herein which provide a unique and practical solution for enabling label-free high throughput screening (HTS) to aid in the discovery of new drugs. In one embodiment, the screening system enables direct binding assays to be performed in which a biomolecular interaction of a chemical compound (drug candidate) with a biomolecule (therapeutic target) can be detected using assay volumes and concentrations that are compatible with the current practices of HTS in the pharmaceutical industry. The screening system also enables the detection of bio-chemical interactions that occurr in the wells of a microplate which incorporates biosensors and surface chemistry to immobilize the therapeutic target at the surface of the biosensors. The screening system also includes fluid handling and plate handling devices to help perform automated HTS assays.

Abstract: Self-referencing optical sensors and methods are described herein that can be used to detect bio-chemical interactions (e.g., biological binding of antigen-antibody pairs) that occur in for example a microplate. In one embodiment, the self-referencing optical sensor includes a substrate, a lower (reference) waveguide grating structure, a buffer layer and an upper (sensing) waveguide grating structure. This self-referencing optical sensor enables an optical interrogation system to detect a bio-chemical interaction independent of the effect of temperature by measuring a reference signal associated with the lower (reference) waveguide grating structure and measuring a sensing signal associated with the upper (sensing) waveguide grating structure. These two signals are then subtracted from one another to determine a sensing measurement that represents whether or not the bio-chemical interaction occurred that is independent of the effect of temperature.

Abstract: In accordance with another exemplary embodiment of the present invention, an optical device includes an interleaver/deinterleaver, which includes a passive thermal compensator, wherein an optical signal which transverses the optical device undergoes substantially no temperature induced frequency drift over a desired temperature range. In accordance with another exemplary embodiment of the present invention, an optical device includes a first element which decomposes the optical signal into a first beam and a second beam with the first beam being in a first polarization state. The first and second polarization states being orthogonal to one another and including each of the multiple channels.