Paper-based analytical device is a robust sensing platform due to their low cost, high availability, biocompatibility, and environmental friendlily properties. However, paper materials often exhibit a strong background signal under UV illumination, limiting their application with fluorescent detections. In this study, an approach combining paper material, copper nanocluster with a large Stokes shift, and thermoplastic lamination is utilized to resolve this problem without the requirement of expensive optical filter setups. The capability of this integrated device is established through cysteine detection by the use of synthesized copper nanoclusters. A digital camera is applied to capture fluorescence changes on the platform and a signal reduction via thiol group induced metal cluster etching is observed. Red-Green-Blue (RGB) color imaging analysis can effectively remove the fluorescence background in absence of optical filters, and the red emission signals from copper nanoclusters can be quantified. The incorporation of thermoplastic films and antioxidative sheets greatly improves device durability under ambient conditions and provides mechanical supports. This integrated design offers a durable, low-cost, optical filter-free, and highly-reduced background fluorescent sensing platform.