Molecular Editing of Flavins for Catalysis

Rehpenn, Andreas; Walter, Alexandra; Storch, Golo

doi:10.1055/a-1458-2419

Cited by 24 publications

(16 citation statements)

References 64 publications

(78 reference statements)

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“…The general usefulness of reduced flavin catalysts is highlighted by recent reductive catalytic reactions with flavoenzymes and a deazaflavin . We found it remarkable that in organic synthesis molecular flavins are extensively applied for oxidations, for example, using commercially available (−)-riboflavin, but they are not applied for reductions. Therefore, we aimed for finding a strategy to use molecular flavins in the reductive 5- exo -trig cyclization of barbituric acid derivatives, which had previously only been reported with superstoichiometric metal reductants (Figure B). , …”

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confidence: 99%

Reduced Molecular Flavins as Single-Electron Reductants after Photoexcitation

et al. 2022

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Flavoenzymes mediate a multitude of chemical reactions and are catalytically active both in different oxidation states and in covalent adducts with reagents. The transfer of such reactivity to the organic laboratory using simplified molecular flavins is highly desirable, and such applications in (photo)oxidation reactions are already established. However, molecular flavins have not been used for the reduction of organic substrates yet, although this activity is known and well-studied for DNA photolyase enzymes. We report a catalytic method using reduced molecular flavins as photoreductants and γ-terpinene as a sacrificial reductant. Additionally, we present our design for air-stable, reduced flavin catalysts, which is based on a conformational bias strategy and circumvents the otherwise rapid reduction of O2 from air. Using our catalytic strategy, we were able to replace superstoichiometric amounts of the rare-earth reductant SmI2 in a 5-exo-trig cyclization of substituted barbituric acid derivatives. Such flavin-catalyzed reductions are anticipated to be beneficial for other transformations as well and their straightforward synthesis indicates future use in stereo- as well as site-selective transformations.

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Reduced Molecular Flavins as Single-Electron Reductants after Photoexcitation

et al. 2022

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“…The unique catalytic properties of 3‐Cl were demonstrated by comparison with neutral deazaflavin 2 b and riboflavin tetraacetate (RFTA), which is a prominent flavin derivative used in photooxidation reactions [17b–d] . As expected, with 2 b and RFTA, the photooxidation of 4 b occurred in good to excellent yield under an oxygen atmosphere.…”

Section: Resultsmentioning

confidence: 76%

“…However, although flavins have been shown to be selective in a few cases, the procedure for oxidizing the benzyl position in the presence of a heteroatom, such as sulfur in sulfides or nitrogen in an amino group, has not been described to date (Scheme 2). [17b,21] Similar to other photocatalysts, the need for oxygen during flavin recovery causes chemoselectivity problems.…”

Section: Resultsmentioning

confidence: 99%

Highly Chemoselective Catalytic Photooxidations by Using Solvent as a Sacrificial Electron Acceptor

Obertík

Chudoba

Šturala

et al. 2022

Chemistry A European J

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Catalyst recovery is an integral part of photoredox catalysis. It is often solved by adding another component‐a sacrificial agent‐whose role is to convert the catalyst back into its original oxidation state. However, an additive may cause a side reaction thus decreasing the selectivity and overall efficiency. Herein, we present a novel approach towards chemoselective photooxidation reactions based on suitable solvent‐acetonitrile acting simultaneously as an electron acceptor for catalyst recovery, and on anaerobic conditions. This is allowed by the unique properties of the catalyst, 7,8‐dimethoxy‐3‐methyl‐5‐phenyl‐5‐deazaflavinium chloride existing in both strongly oxidizing and reducing forms, whose strength is increased by excitation with visible light. Usefulness of this system is demonstrated in chemoselective dehydrogenations of 4‐methoxy‐ and 4‐chlorobenzyl alcohols to aldehydes without over‐oxidation to benzoic acids achieving yields up to 70 %. 4‐Substituted 1‐phenylethanols were oxidized to ketones with yields 80–100 % and, moreover, with yields 31‐98 % in the presence of benzylic methyl group, diphenylmethane or thioanisole which are readily oxidized in the presence of oxygen but these were untouched with our system. Mechanistic studies based on UV‐Vis spectro‐electrochemistry, EPR and time‐resolved spectroscopy measurements showed that the process involving an electron release from an excited deazaflavin radical to acetonitrile under formation of solvated electron is crucial for the catalyst recovery.

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“…Flavins can catalyze a range of reactions [3c,22] . Previous work on the use of a gelling flavin derivative for aerobic hydrogenation of olefins showed that the gel phase provided enhanced catalysis compared to the equivalent non‐gelled catalyst due to the formation of reaction cavities [10b] .…”

Section: Resultsmentioning

confidence: 99%