A ratiometric fluorescent platform based on xylan-derived carbon dots for detecting Vibrio parahaemolyticus
Xiwen Feng, Shanshan Yu, Jihai Cai, Xiaoying Wang
Abstract
It is a challenge to design a ratiometric fluorescent platform with a stable inner reference free from disturbing for detection. Herein, a ratiometric fluorescent platform (RFP) was fabricated for detection of Vibrio parahaemolyticus ( V. parahaemolyticus ) based on optically transparent silica nanoparticles which integrates fluorophores and specific aptamers. The platform incorporated Rhodamine B as an internal reference within the protective silica matrix, while xylan-derived carbon dots were evenly distributed on silica’s surface. When excited at 365 nm, RFP exhibited blue fluorescence at 430 nm and orange fluorescence at 575 nm. Blue fluorescence of these carbon dots was quenched through interaction with a Dabcyl-modified aptamer (Apt.D). Upon bacterial addition, changes in the fluorescence intensities were observed, enabling sensitive and ratiometric detection. Notably, this RFP-Apt.D has a low detection limit of 1.15 CFU/mL (S/N = 3) with a linear detection range from 8 CFU/mL to 8 ×10 5 CFU/mL in a short responding time of 30 minutes, which was superior to most reported V. parahaemolyticus sensors. Furthermore, the RFP-Apt.D was successfully applied to detect V. parahaemolyticus in seawater and clam samples through a fast pretreatment without requiring enrichment and achieved reliable and satisfactory recoveries. This work provides a widely adaptable platform to design ratiometric fluorescent sensor for detection of foodborne pathogen. • Xylan-based carbon dots was used to fabricate ratiometric fluorescent platform. • Fluorescence at 432, 575 nm provides internal ratio calibration against interference. • The transparent silica nanoparticles improve the stability of fluorescent reference. • The fluorescent platform shows trace detection for Vibrio parahaemolyticus . • Linear detection range is 8–8 × 10 5 CFU/mL with LOD of 1.15 CFU/mL in 30 min.