Construction of an enzyme-free biosensor utilizing CuO nanoparticles enriched in DNA polymer to catalyze a click chemistry reaction for SERS detection of the p53 gene.

The p53 gene is a known cancer marker. We report a novel protocol for the SERS tandem strategy to detect the p53 gene with high sensitivity. Herein, the click reaction between azide and alkyne was catalyzed by utilizing copper oxide nanoparticles (CuONPs), which were enriched by a T-DNA-triggered hybridization chain reaction (HCR). The T-DNA signal was amplified by establishing the correlation between the T-DNA signal and the concentration of CuONPs in a nonenzymatic isothermal environment. In contrast to other Raman reporters, we used alkynyl compounds as Raman reporters, which showed excellent characteristics in the Raman-silent region (1800-2800 cm). Therefore, the highly sensitive and highly selective SERS signals could be obtained in complex biological matrices. Due to utilizing multistep amplification strategies, including the nanoparticle-modified HCR polymer and "click" reaction, the limit of detection (LOD) and the limit of quantification (LOQ) of this sensor could be as low as 0.0174 pM and 0.0583 pM, respectively. The accuracy of the strategy expressed as the RSD was in the range of 3.14%-6.21%. The results indicated that the constructed sensor has excellent performance for the detection of the p53 gene in serum samples in a low concentration range, which suggests that the proposed enzyme-free SERS analytical sensor has good clinical application prospects.