Novel disposable biochip platform employing supercritical angle fluorescence for enhanced fluorescence collection.

This paper presents an overview of development of a novel disposable plastic biochip for multiplexed clinical diagnostic applications. The disposable biochip is manufactured using a low-cost, rapid turn- around injection moulding process and consists of nine parabolic elements on a planar substrate. The optical elements are based on supercritical angle fluorescence (SAF) which provides substantial enhancement of the fluorescence collection efficiency but also confines the fluorescence detection volume strictly to the immediate proximity of the biochip surface, thereby having the potential to discriminate against background fluorescence from the analyte solution. An optical reader is also described that enables interrogation and fluorescence collection from the nine optical elements on the chip. The sensitivity of the system was determined with a biotin-avidin assay while its clinical utility was demonstrated in an assay for C-reactive protein (CRP), an inflammation marker.

Surface plasmon-coupled emission (SPCE)-based immunoassay using a novel paraboloid array biochip.

We have carried out a human IgG immunoassay on a novel disposable optical array biochip using surface plasmon-coupled emission (SPCE) detection. The work successfully combines the advantages of the highly directional SPCE emission profile and enhanced surface plasmon excitation with the high light collection efficiency achieved using supercritical angle fluorescence (SAF). This is achieved using an array of transparent paraboloid polymer elements which have been coated with a thin gold layer to facilitate SPCE. Moreover, since only the emission of molecules which are close to the metal surface couple into the surface plasmon, the detection is highly surface-specific leading to background suppression and increased signal-to-noise ratio. Theoretical calculations have been carried out in order to match the surface plasmon resonance angles and SPCE emission angles to the paraboloid array features for light collection. A sandwich assay format was used and a dose response curve was obtained in the concentration range 2 ng/ml to 200 microg/ml yielding a limit of detection of 20 ng/ml. This is the first demonstration of an SPCE-based assay on a disposable biochip platform and indicates the potential of SPCE-based arrays for high-throughput analysis of biomolecular interactions.

Experimental and theoretical evaluation of surface plasmon-coupled emission for sensitive fluorescence detection.

Surface plasmon-coupled emission (SPCE) is a phenomenon whereby the light emitted from a fluorescent molecule can couple into the surface plasmon of an adjacent metal layer, resulting in highly directional emission in the region of the surface plasmon resonance (SPR) angle. In addition to high directionality of emission, SPCE has the added advantage of surface selectivity in that the coupling diminishes with increasing distance from the surface. This effect can be exploited in bioassays whereby a fluorescing background from the sample can be suppressed. We have investigated, both theoretically and experimentally, the SPCE effect for a Cy5-spacer-Ag layer system. Both the angular dependence of emission and the dependence of SPCE emission intensity on Cy5-metal separation were investigated. It is demonstrated that SPCE leads to lower total fluorescence signal than that obtained in the absence of a metal layer. This is the first experimental verification of the reduction in SPCE intensity compared to the metal-free case. Our results are in a good agreement with theoretical models. The validation of the theoretical model provides a basis for optimizing biosensor platform performance, particularly in the context of the advantages offered by SPCE of highly directional emission and surface selectivity.