Highly Sensitive and Selective Real-Time Breath Isoprene Detection using the Gas Reforming Reaction of MOF-Derived Nanoreactors.
Seon Ju ParkYoung Kook MoonSei-Woong ParkSoo Min LeeTae-Hyun KimSoo Young KimJong-Heun LeeYoung-Moo JoPublished in: ACS applied materials & interfaces (2023)
Real-time breath isoprene sensing provides noninvasive methods for monitoring human metabolism and early diagnosis of cardiovascular diseases. Nonetheless, the stable alkene structure and high humidity of the breath hinder sensitive and selective isoprene detection. In this work, we derived well-defined Co 3 O 4 @polyoxometalate yolk-shell structures using a metal-organic framework template. The inner space, including highly catalytic Co 3 O 4 yolks surrounded by a semipermeable polyoxometalate shell, enables stable isoprene to be reformed to reactive intermediate species by increasing the gas residence time and the reaction with the inner catalyst. This sensor exhibited selective isoprene detection with an extremely high chemiresistive response (180.6) and low detection limit (0.58 ppb). The high sensing performance can be attributed to electronic sensitization and catalytic promotion effects. In addition, the reforming reaction of isoprene is further confirmed by the proton transfer reaction-quadrupole mass spectrometry analysis. The practical feasibility of this sensor in smart healthcare applications is exhibited by monitoring muscle activity during the workout.
Keyphrases
- metal organic framework
- mass spectrometry
- loop mediated isothermal amplification
- healthcare
- label free
- real time pcr
- cardiovascular disease
- room temperature
- liquid chromatography
- endothelial cells
- electron transfer
- type diabetes
- high performance liquid chromatography
- carbon dioxide
- gold nanoparticles
- metabolic syndrome
- gas chromatography
- coronary artery disease
- crystal structure
- tandem mass spectrometry
- single molecule
- health information