Microsphere amplified fluorescence and its application in sensing.

The far-field fluorescence amplification, the intense fluorescence emission addresses the great potential in sensitive detection to large biomolecules, was seriously ignored for the failure in amplifying the weak fluorescence excepting the electromagnetic field (EM) induced fluorescence amplification on the metallic surfaces. Here, a microsphere in hundreds of micrometers was adopted to proceed with the fluorescence amplification via building up a local dielectric surrounding for fluorophore. The wide range of contribution-angle fluorescence could be efficiently restricted within the microsphere by facilitating the energy of reflection restraining and declining the energy of refraction decaying and the intense fluorescence emission confined within the microsphere could be directly observed. The proposed microsphere amplified fluorescence was demonstrated to induce about 2600 times of improved sensitivity in the detection of the fluorescent resorufin referring that of the original resorufin solution through the laser induced fluorescence (LIF). Furthermore, the limit of detection (LOD) of human IgA was successfully obtained to 3.25 fM through the microsphere in 47.7 pL when the microsphere amplified fluorescence was utilized in the fluoroimmunoassay. We believe the microsphere amplified fluorescence would be a potential strategy to implement the sensitive fluorescence sensing.

Droplet Sensitized Fluorescence Detection for Enzyme-Linked Immune Sorbent Assays on Microwell Plate.

The microwell plate/microtiter plate is among the most widely used tools in immune assays. In this paper, we report on a sensitive method for enhancing fluorescence emission detection by simply adding several droplets of an immiscible organic compound into the microwells before detection. To prove the concept, human IgA was determined on a microwell plate using this droplet enhanced fluorescence (DEF) detection method. An obvious enhancement in fluorescence was observed. The detection limit (LOD) was about 1/20 times and the sensitivity was 4 times greater than that without droplets. To prove the use of the method for disease diagnosis, the IgG of measles in human plasma was determined using the proposed DEF method. A LOD of around 1/5 times and a sensitivity of 4 times the DEF were easily achieved compared to ELISA with a conventional fluorescence detection.