A Study of the Mechanisms and Characteristics of Fluorescence Enhancement for the Detection of Formononetin and Ononin

Overview

Journal Molecules

Publisher MDPI

Specialty Biology

Date 2023 Feb 25

PMID 36838530

Authors

Jinjin Cao

Tingting Li

Ting Liu

Yanhui Zheng

Jiamiao Liu

Qifan Yang

Xuguang Li

Wenbo Lu

Yongju Wei

Wenhong Li

Affiliations

Soon will be listed here.

Abstract

In this work, the origins for the spectral difference between two isoflavones, formononetin (F) and ononin (FG), are revealed via a comparison study of the fluorescence molecular structure. The fluorescence enhancement of FG in hot alkaline conditions is reported for the first time. For F, there is almost no fluorescence under acidic conditions, but when the pH is >4.8, its fluorescence begins to increase due to the deprotonation of 7-OH. Under a pH between 9.3 and 12.0, the anionic form of F produces a strong and stable fluorescence. The fluorescence quantum yield (Yf) of F is measured to be 0.042. FG shows only weak fluorescence in aqueous solutions under a wide range of pH until it is placed in hot alkaline solutions, which is attributed to the cleavage reaction of the γ-pyrone ring in FG. The Yf of FG is determined to be 0.020. Based on the fluorescence sensitization methods of F and FG, the quantitative analysis and detection of two substances can be realized. The limit of the detections for F and FG are 2.60 ng·mL and 9.30 ng·mL, respectively. The linear detection ranges of F and FG are 11.7~1860 ng·mL and 14.6~2920 ng·mL, respectively. Although the structural relationship between F and FG is glycoside and aglycone, under hot alkaline conditions, the final products after the cleavage and hydrolysis reactions are essentially different. The different fluorescence characteristics between F and FG pave a way for further identification and a quantitative analysis of the corresponding components in Chinese herbal medicine.

Citing Articles

Identification of the Metabolites of Both Formononetin in Rat Hepatic S9 and Ononin in Rat Urine Samples and Preliminary Network Pharmacology Evaluation of Their Main Metabolites.

Yang Y, Wang T, Chen Q, Chen H, He Q, Zhang Y Molecules. 2023; 28(21).

PMID: 37959870 PMC: 10648658. DOI: 10.3390/molecules28217451.

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