Nanodomain-Enhanced Stable and Multifunctional Probes with Near 100% Quantum Yield for Versatile Biosensing
Zihan Zhang, Niu Feng, Xiaobo Hu, Xufeng Wang, Jiacheng Tao, Zhenguang Ji, Yue Yang, Jimei Ma, Yiping Chen
Abstract
The preparation of high quantum yield, stable, and multifunctional fluorescent probes is of great significance in the fields of biomedicine and photoelectric sensing. Here, a triphenylamine-based D-π-A fluorescent molecule (TPA-CN) was designed and prepared, demonstrating a fluorescence quantum yield of 88.84%. With a polystyrene nanosphere as the carrier, TPA-CN was encapsulated inside the nanosphere to form intra-nanosphere confining domains. These nanodomain-enhanced fluorescent nanospheres exhibited a fluorescence quantum yield of 98.21%. Using antigen-antibody specificity and the selective catalytic activity of a bioenzyme, with chloramphenicol as a model target, a dual-signal readout biosensor (in fluorescence and colorimetric modes) was designed for ultrasensitive and instrument-free determination. The detection limit was 24 pg/mL within 30 min in fluorescence mode, 38-fold more sensitive and 10-fold faster than that of enzyme linked immunosorbent assays. The nanodomain-enhanced fluorescent probes and dynamic biosensor provide a robust and versatile solution for public health and environmental monitoring needs.