1. Facile synthesis of nitrogen-doped carbon dots as sensitive fluorescence probes for selective recognition of cinnamaldehyde and l-Arginine/l-Lysine in living cells.
- Author
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Wei, Shanshan, Shi, Xinyuan, Wang, Chenzhao, Zhang, Hongyuan, Jiang, Chunzhu, Sun, Guoying, and Jiang, Chunhuan
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AMINO acid metabolism disorders , *DOPING agents (Chemistry) , *FLUORESCENCE , *HYDROTHERMAL carbonization , *FLUORESCENT probes - Abstract
One-pot synthesis of N -CDs was applied as a highly efficient "ON-OFF-ON" fluorescent probe for the rapid detection of CAL and l -Arg/ l -Lys in living cells. As a consequence, these N -CDs as a powerful analysis tool displayed more prominent and influential ability in real-time monitoring CAL and l -Arg/ l -Lys, and might offer a new opportunity for exploring the physiological and pathological processes of amino acid metabolism diseases. [Display omitted] • The nitrogen-doped carbon dots (N -CDs) were synthesized via a simple one-step hydrothermal method. • These CDs could rapidly and selectively detect CAL and l -Arg/ l -Lys with the detection limits as low as 58 nM, 18 nM/16 nM, respectively. • The N -CDs as a fluorescent probe displayed low toxicity and were suitable for sensing CAL and l -Arg/ l -Lys in living cells. The disorder of amino acid metabolism and the abuse of small molecule drugs pose serious threats to public health. However, due to the limitations of existing detection technologies in sensing cinnamaldehyde (CAL) and l -Arginine/ l -Lysine (l -Arg/ l -Lys), there is an urgent need to develop new sensing strategies to meet the severe challenges currently facing. Herein, nitrogen-doped carbon dots (N -CDs) were developed using a simple one-pot hydrothermal carbonization method. These N -CDs exhibited numerous distinctive characteristics such as excellent photoluminescence, high water dispersibility, favorable biocompatibility, and superior chemical inertness. Strikingly, the as-prepared CDs as a highly efficient fluorescent probe possessed significant sensitivity and selectivity toward CAL and l -Arg/ l -Lys over other analytes with a low detection limit of 58 nM and 16 nM/18 nM, respectively. The fluorescence of N -CDs could be quenched by CAL through an electron transfer process. Then, the strong electrostatic interaction between l -Arg/ l -Lys and N -CDs induced the efficient fluorescence recovery. More importantly, the outstanding biosafety and excellent analyte-responsive fluorescence characteristics of N -CDs have also been verified in living cells as well as in serum and urine. Overall, the N -CDs had a wide application prospect in the diagnosis of amino acid metabolic diseases and small molecule drug sensing. [ABSTRACT FROM AUTHOR]
- Published
- 2023
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