Enhanced luminescence and stability of TFMDSA nanoparticles via polymer-induced aggregation for bioimaging

Abstract

In recent years, fluorescence imaging has occupied a very important position in the life science and biomedical fields. However, achieving nanomaterials for bioimaging with both high fluorescence quantum efficiency and high stability remains a significant challenge. Herein, we synthesized mPEG_5K–PCL_10K@TFMDSA and mPEG_5K–PLLA_10K@TFMDSA nanoparticles using polymer-induced aggregation. This method significantly enhanced the luminescence efficiency of TFMDSA nanoparticles in solution, attributed to improved intermolecular interactions and restricted molecular vibrations. The resulting nanoparticles exhibited exceptional optical stability over a period of seven days and demonstrated low cytotoxicity towards HeLa cells, making them highly suitable for bioimaging applications. Cellular uptake studies indicated that these nanoparticles were more efficiently internalized by HeLa cells compared to their amorphous counterparts, likely due to their unique square morphology. Our findings highlight the potential of polymer-induced aggregation in enhancing the optical properties and stability of TFMDSA nanomaterials, suggesting their promise as biofluorescent probes for cancer diagnosis and other biomedical applications.