posted on 2024-08-09, 10:29authored byMing Qian, Yuan Ye, Tian-Bing Ren, Bin Xiong, Lin Yuan, Xiao-Bing Zhang
Small-molecule fluorescent probes
have emerged as potential tools
for cancer cell imaging-based diagnostic and therapeutic applications,
but their limited selectivity and poor imaging contrast hinder their
broad applications. To address these problems, we present the design
and construction of a novel near-infrared (NIR) biotin-conjugated
and viscosity-activatable fluorescent probe, named as QL-VB, for selective recognition and imaging of cancer cells. The designed
probe exhibited a NIR emission at 680 nm, with a substantial Stokes
shift of 100 nm and remarkably sensitive responses toward viscosity
changes in solution. Importantly, QL-VB provided an evidently
enhanced signal-to-noise ratio (SNR: 6.2) for the discrimination of
cancer cells/normal cells, as compared with the control probe without
biotin conjugation (SNR: 1.8). Moreover, we validated the capability
of QL-VB for dynamic monitoring of stimulated viscosity
changes within cancer cells and employed QL-VB for distinguishing
breast cancer tissues from normal tissues in live mice with improved
accuracy (SNR: 2.5) in comparison with the control probe (SNR: 1.8).
All these findings indicated that the cancer-targeting and viscosity-activatable
NIR fluorescent probe not only enables the mechanistic investigations
of mitochondrial viscosity alterations within cancer cells but also
holds the potential as a robust tool for cancer cell imaging-based
applications.