The World Health Organization reports that seasonal influenza (flu) epidemics result in 3 to 5 million cases of severe illness with upwards of 500,000 deaths. In the United States, 200,000 hospitalizations and 36,000 deaths occur annually with an economic burden of $87 billion. Hence, there is an urgent need to develop highly-sensitive, low-cost diagnostics for use at the point-of-care (POC) to facilitate immediate treatment at the early stages of infection. POC diagnostics can be implemented in paper-based, lateral flow assays to capture influenza nucleoproteins (NPs) with antibodies. Despite their utility, these assays suffer from moderately poor sensitivity. The highest sensitivity measured in a study evaluating six common colloidal gold colorimetric flu tests was 71%. To improve assay sensitivity, fluorescence detection has been demonstrated to detect analyte concentrations 1000-fold lower than with colloidal gold in lateral flow assays. My project aims to develop a fluorescence-based immunoassay for influenza A NPs to achieve improved sensitivities over those of colorimetric tests. The assay is carried out on lateral flow strips, making it readily translatable to point-of-care use. Upon capture of NP by immobilized antibodies, a biotinylated immunoglobulin G (IgG) binds to the NP at a different epitope. Subsequently, streptavidin-bound horseradish peroxidase (HRP) binds to the IgG. HRP oxidizes dihydrorhodamine 6G, a non-fluorescent substrate, into the fluorophore rhodamine 6G (R6G). Hence, an observable fluorescent signal is generated in the presence of NP. In preliminary experiments, R6G adsorbed to the membrane; R6G accumulates near HRP, increasing the signal-to-background ratio. An immunoassay for NP shows observable fluorescence signals at the capture and control regions for their respective positive and negative sample conditions. The remainder of the project aims to optimize reagent concentrations to further improve the assay’s sensitivity. Ultimately, the fluorescence-based assay developed would serve as a translatable platform for highly-sensitive detection of other viral analytes.