Detection of 2,4-Dinitrophenol and Bio-Imaging Application with Agaric-Based Nitrogen-Doped Carbon Quantum Dots (N-CQDs)

Abstract: With agaric as carbon source and urea as nitrogen source, this paper has successfully synthesized nitrogen-doped carbon quantum dots (N-CQDs) by simple one-step hydrothermal method. A series of analysis have been used to make characterization of the physical, chemical structures and optical performance of N-CQDs. The fluorescence stability was studied by examining the ionic strength, pH value and storage time and other conditions. The cytotoxicity and bacterial toxicity of N-CQDs were applied to biological ima… Show more

“…developed agaric‐based N‐CQDs for cell imaging and demonstrated over 90% viability for HT 29 cells. [ 462 ] Moreover, blue, green, and red fluorescence were easily observed when excited by 405, 488, and 552 nm laser scanning confocal microscope, respectively, suggesting a high possibility of using agaric‐based N‐CQDs as a probe for live‐cell and tissue imaging. However, similar to GQDs, N‐CQDs will convert into g‐CNQDs by increasing nitrogen concentration in the framework.…”

Emerging Trends of Carbon‐Based Quantum Dots: Nanoarchitectonics and Applications

“…developed agaric‐based N‐CQDs for cell imaging and demonstrated over 90% viability for HT 29 cells. [ 462 ] Moreover, blue, green, and red fluorescence were easily observed when excited by 405, 488, and 552 nm laser scanning confocal microscope, respectively, suggesting a high possibility of using agaric‐based N‐CQDs as a probe for live‐cell and tissue imaging. However, similar to GQDs, N‐CQDs will convert into g‐CNQDs by increasing nitrogen concentration in the framework.…”

Emerging Trends of Carbon‐Based Quantum Dots: Nanoarchitectonics and Applications

Enhanced anti-cancer effects of magnetic targeted pH-sensitive curcumin delivery system based on heterogeneous magnetic α-Fe2O3/Fe3O4 nanoparticles on gastric cancer SGC-7901 cells

Facile green synthesis and characterization of fluorescent nanoprobe based on Ca, K, N-doped carbon quantum dots derived from Aegle marmelos for bioimaging of human neuroblastoma cancer cells and living organisms