期刊
CHEMICAL ENGINEERING JOURNAL
卷 455, 期 -, 页码 -出版社
ELSEVIER SCIENCE SA
DOI: 10.1016/j.cej.2022.140521
关键词
Layered metal chalcogenides; Antibiotics; Electrochemical sensor; Low-level detection; Real-time analysis; Nitrofurazone
The increasing global demands for monitoring the healthcare and environmental system have led to a higher usage of antibodies. However, the uncontrolled utilization and disposal of the antibiotic nitrofurazone (NF) have caused serious ecological issues. Therefore, a sensitive electrochemical method using tin selenide (SnSe) integrated with hexagonal boron nitride (h-BN) as an electrode material for the real-time and low-level detection of NF has been developed. The SnSe/h-BN electrode demonstrates excellent electrochemical activity, dual linear ranges, a low limit of detection, and high sensitivity, making it feasible for the rapid and real-time analysis of NF in water and urine samples.
Rising global demands for monitoring the health care and environmental system have increased the usage of antibodies as they are forced to deal with food products and environmental samples. Nitrofurazone (NF) is an important antibiotic that is widely used in clinical treatments, but its uncontrolled utilization and disposal wastage cause serious global issues into the ecosystem. Thus, a sensitive electrochemical method is developed for the real-time and low-level detection of NF. Layered metal chalcogenides of tin selenide (SnSe) integrated with hexagonal boron nitride (h-BN) are prepared as an electrode material for the detection of NF to take advantage of the unique structural and physiochemical properties of SnSe and h-BN. The physicochemical characteristics of SnSe/h-BN composite are determined with various spectral and analytical methods. The fabricated SnSe/h-BN electrode possesses excellent electrochemical activity for the detection of NF, with dual linear ranges of 0.001-12.12 mu M and 15.2-342.2 mu M, a low limit of detection of 0.34 nM, and a high sensitivity of 1.927 mu A mu M-1 cm(-2). The superior performance could be attributed to the higher active surface area of the SnSe/h-BN composite and a synergistic effect between SnSe and h-BN that enhances the kinetics of the electron transfer over the electrode-electrolyte interface. The SnSe/h-BN electrode also achieves a satisfactory response level for the detection of NF in water and urine samples, thus indicating its feasibility for the rapid, low-level detection, and real-time analysis of NF.
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