A novel dual-signal molecularly imprinted electrochemical sensor based on NiFe prussian blue analogue and SnS2 for detection of p-Hydroxyacetophenone

“…(1) As can be seen from Figure S21, the current response of PBA/UiO-66/NF to glucose gradually increased as the reaction time increased from 6 to 24 h. However, when the reaction time was up to 32 h, the current response of PBA/UiO-66/NF to glucose started to decrease. A double reduction peak can be found in the CV curves of 6 h-PBA/UiO-66/NF and 48 h-PBA/UiO-66/NF, which had also been reported in previous reports . (2) Figure S22 shows that when the reaction temperature was 90 °C, the as-synthesized material, namely, 90 °C-PBA/UiO-66/NF, showed the highest current response to glucose compared to the other three materials.…”

“…A double reduction peak can be found in the CV curves of 6 h-PBA/UiO-66/NF and 48 h-PBA/UiO-66/NF, which had also been reported in previous reports. 62 (2) Figure S22 shows that when the reaction temperature was 90 °C, the as-synthesized material, namely, 90 °C-PBA/UiO-66/NF, showed the highest current response to glucose compared to the other three materials. (3) Figure S23 shows that 0.6 mmol-PBA/UiO-66/ NF had the strongest electrocatalytic capacity for glucose among these four materials.…”

UiO-66-Derived PBA Composite as Multifunctional Electrochemical Non-Enzymatic Sensor Realizing High-Performance Detection of Hydrogen Peroxide and Glucose

“…(1) As can be seen from Figure S21, the current response of PBA/UiO-66/NF to glucose gradually increased as the reaction time increased from 6 to 24 h. However, when the reaction time was up to 32 h, the current response of PBA/UiO-66/NF to glucose started to decrease. A double reduction peak can be found in the CV curves of 6 h-PBA/UiO-66/NF and 48 h-PBA/UiO-66/NF, which had also been reported in previous reports . (2) Figure S22 shows that when the reaction temperature was 90 °C, the as-synthesized material, namely, 90 °C-PBA/UiO-66/NF, showed the highest current response to glucose compared to the other three materials.…”

“…A double reduction peak can be found in the CV curves of 6 h-PBA/UiO-66/NF and 48 h-PBA/UiO-66/NF, which had also been reported in previous reports. 62 (2) Figure S22 shows that when the reaction temperature was 90 °C, the as-synthesized material, namely, 90 °C-PBA/UiO-66/NF, showed the highest current response to glucose compared to the other three materials. (3) Figure S23 shows that 0.6 mmol-PBA/UiO-66/ NF had the strongest electrocatalytic capacity for glucose among these four materials.…”

UiO-66-Derived PBA Composite as Multifunctional Electrochemical Non-Enzymatic Sensor Realizing High-Performance Detection of Hydrogen Peroxide and Glucose

“…; M = Co, Fe, Mn, etc.). 4 PB and PBAs have been broadly applied as electrochemical sensors as reported in previous literature, including sensing guanine, hydrogen peroxide, carcinoembryonic antigen, glucose, uric acid, 2-nitrophenol, and p-hydroxyacetophenone, [5][6][7][8][9][10] due to their specific advantages. (1) Their open framework can provide abundant 3D channels, that are very beneficial for diffusion of charge carrier ions, endowing electron-transport property.…”

One-step synthesis of 2D@3D hollow Prussian blue analogue as a high-performance bifunctional electrochemical sensor

“…[9] Due to the expensive cost and complicated pre-processing steps, the application of these methods is greatly limited. In recent years, electrochemical methods have attracted attention due to their advantages of simple operation, short analysis time and high sensitivity, which have been widely used in the detection of food, [10] drugs [11] and vital substances. [12] Different kinds of electrochemical sensors for detecting resveratrol have been reported in many studies.…”

Molecularly Imprinted Electrochemical Sensor Based on Nitrogen‐doped Molybdenum Carbide Nanosphere for Trace Analysis of Resveratrol