Catalytic micromotors as self-stirring microreactors for efficient dual-mode colorimetric detection

• Published in: Journal of colloid and interface science Vol. 643; pp. 196 - 204
• Main Authors: Zhao, He, Zeng, Huarou, Chen, Ting, Huang, Xiaoying, Cai, Yuepeng, Dong, Renfeng
• Format: Journal Article
• Language: English
• Published: United States Elsevier Inc 01.08.2023
• Subjects: Catalytic; Colorimetry; Magnetically-driven; Micromotor; Microreactor; Micromotor; Catalytic; Colorimetry; Microreactor; Magnetically-driven
• ISSN: 0021-9797; 1095-7103
• DOI: 10.1016/j.jcis.2023.03.144

Catalytic micromotor enable efficient dual-mode colorimetric detection by self-stirring microreaction. [Display omitted] A catalytic micromotor-based (MIL-88B@Fe3O4) colorimetric detection system which exhibit rapid color reaction for quantitative colorimetry and high-throughput testing for qualitative colorimetry have been successfully developed. Taking the advantages of the micromotor with dual roles (micro-rotor and micro-catalyst), under rotating magnetic field, each micromotor represents a microreactor which have micro-rotor for microenvironment stirring and micro-catalyst for the color reaction. Numerous self-string micro-reactions rapidly catalyze the substance and show the corresponding color for the spectroscopy testing and analysis. Additionally, owing to the tiny motor can rotate and catalyze within microdroplet, a high-throughput visual colorimetric detection system with 48 micro-wells has been innovatively conducted. The system enables up to 48 microdroplet reactions based on micromotors run simultaneously under the rotating magnetic field. Multi-substance, including their species difference and concentration strength, can be easily and efficiently identified by observing the color difference of the droplet with naked eye after just one test. This novel catalytic MOF-based micromotor with attractive rotational motion and excellent catalytic performance not only endowed a new nanotechnology to colorimetry, but also shows hold great potentials in other fields, such as refined production, biomedical analysis, environmental governance etc., since such micromotor-based microreactor can be easily applied to other chemical microreactions.