A fluorescent dual-emitting platform for fluorescent turn-on ratiometric detection of ascorbic acid in beverages utilizing luminol-embedded iron-based metal-organic frameworks

A fluorescent dual-emitting platform for fluorescent turn-on ratiometric detection of ascorbic acid in beverages was developed utilizing luminol-embedded iron-based metal-organic frameworks (luminol@Fe-DOBDC MOFs). Luminol@Fe-DOBDC MOFs with fluorescent emissions at 430 nm and 540 nm under excitation wavelength of 365 nm were applied to detect ascorbic acid on the basis of ascorbic acid triggering the reduction of Fe3+ into Fe2+. In the presence of ascorbic acid, fluorescent intensity at 540 nm was increased significantly while fluorescent intensity at 430 nm was changed slightly. Two emission peaks separated by 110 nm can eliminate environmental interferences by built-in self-calibration of ratiometric signal, enhancing the sensitivity and accuracy. The increasing ratiometric fluorescent intensity (I540 nm/I430 nm) has linear relationship with the concentration of ascorbic acid from 0.2 to 30 mu M with limit of detection of 70 nM. It is an efficient, sensitive and accurate platform to detect ascorbic acid in commercial beverages using transition-metal-based MOFs.

Automated summary

In this study, a fluorescent dual-emitting platform was developed for accurate detection of ascorbic acid in beverages. The platform utilized luminol-embedded iron-based metal-organic frameworks and relied on the reduction of Fe3+ into Fe2+ triggered by ascorbic acid. By utilizing two separate emission peaks, environmental interferences were eliminated, resulting in enhanced sensitivity and accuracy.