Oxygen mediated oxidative couplings of flavones in alkaline water

Catalyzed oxidative C-C bond coupling reactions play an important role in the chemical synthesis of complex natural products of medicinal importance. However, the poor functional group tolerance renders them unfit for the synthesis of naturally occurring polyphenolic flavones. We find that molecular...

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Bibliographic Details
Published in:Nature communications 2022-10, Vol.13 (1), p.6424-6424, Article 6424
Main Authors: Yang, Xin, Lim, Sophie Hui Min, Lin, Jiachen, Wu, Jie, Tang, Haidi, Zhao, Fengyue, Liu, Fang, Sun, Chenghua, Shi, Xiangcheng, Kuang, Yulong, Toy, Joanne Yi Hui, Du, Ke, Zhang, Yuannian, Wang, Xiang, Sun, Mingtai, Song, Zhixuan, Wang, Tian, Wu, Ji’en, Houk, K. N., Huang, Dejian
Format: Article
Language:English
Subjects:
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Alkaline water
Availability
Catalysis
Catalysts
Cations
Chemical reactions
Chemical synthesis
Computational chemistry
Computer applications
Coupling (molecular)
Couplings
Dimers
Flavones
Flavonoids
Functional groups
Humanities and Social Sciences
Hydrogen atoms
Medical treatment
multidisciplinary
Natural products
Oxidants
Oxidative Coupling
Oxidizing agents
Oxygen
Oxygen - chemistry
Science
Science (multidisciplinary)
Trimers
Water
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Summary:Catalyzed oxidative C-C bond coupling reactions play an important role in the chemical synthesis of complex natural products of medicinal importance. However, the poor functional group tolerance renders them unfit for the synthesis of naturally occurring polyphenolic flavones. We find that molecular oxygen in alkaline water acts as a hydrogen atom acceptor and oxidant in catalyst-free (without added catalyst) oxidative coupling of luteolin and other flavones. By this facile method, we achieve the synthesis of a small collection of flavone dimers and trimers including naturally occurring dicranolomin, philonotisflavone, dehydrohegoflavone, distichumtriluteolin, and cyclodistichumtriluteolin. Mechanistic studies using both experimental and computational chemistry uncover the underlying reasons for optimal pH, oxygen availability, and counter-cations that define the success of the reaction. We expect our reaction opens up a green and sustainable way to synthesize flavonoid dimers and oligomers using the readily available monomeric flavonoids isolated from biomass and exploiting their use for health care products and treatment of diseases. Catalysed oxidative C-C bond formation reactions are important in the synthesis of natural products, but poorly tolerated by polyphenolic flavones. Here the authors report the reactivity of molecular oxygen in alkaline water without added catalyst for the synthesis of a collection of flavone dimers and trimers.
ISSN:2041-1723
2041-1723
DOI:10.1038/s41467-022-34123-w