Hydrogen peroxide sensor using the biomimetic structure of peroxidase including a metal organic framework

In this study, hemin that has excellent catalytic activity is adopted as a catalyst component and other materials, such as metal organic framework (MOF) and carbon nanotube (CNT), are further used to alleviate drawbacks of hemin, such as location issue and molecular aggregation. Based on that, a new catalyst consisting of heminencapsulated MOF and CNT is developed (Hemin subset of MIL-88-NH2/CNT). To evaluate its catalytic activity, colorimetric and electrochemical evaluations are conducted. When colorimetric method is used, Hemin subset of MIL-88-NH2/CNT shows good catalytic activity due to proper interaction between water media and amine bond of MOF. In electrochemical evaluations, Hemin subset of MIL-88-NH2/CNT has high sensitivity (0.538 mu A mu M(-1)cm(-2)) and low detection limit (0.06 mu M) at 0.5-203 mu M (R-2 = 0.999). Even in amperometric response tests, when 10 mu M H2O2 is injected, Hemin subset of MIL-88-NH2/CNT shows a better response than other heme protein- based catalysts ((Hb, Mb and HRP)/CNT) by 2.06-3.26 times. In terms of stability, its catalytic activity is well preserved even under harsh pH and temperature conditions for a long time (89.5% of the initial value after 15 days). With that, it is confirmed that the Hemin subset of MIL-88-NH2/CNT as the catalyst for use in H2O2 sensors is attractive and better than other heme proteins.

Automated summary

A novel catalyst consisting of heminencapsulated MOF and CNT was developed, demonstrating good catalytic activity and stability for H2O2 sensors, outperforming other catalysts. The catalyst exhibited high sensitivity and low detection limit in electrochemical evaluations, showing potential for practical applications.