A reaction mode of carbene-catalysed aryl aldehyde activation and induced phenol OH functionalization

Chen, Xingkuan; Wang, Hongling; Doitomi, Kazuki; Ooi, Chong Yih; Zheng, Pengcheng; Liu, Wangsheng; Guo, Hao; Yang, Song; Song, Baoan; Hirao, Hajime; Robin, Yonggui

doi:10.1038/ncomms15598

Cited by 57 publications

(41 citation statements)

References 53 publications

(49 reference statements)

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“…[11b] Following these studies,s everal approaches to extend this reactivity to carbocyclic aromatic systems have emerged. [13] These contributions have expanded the scope of carbene catalysis,w hile simultaneously presenting opportunities to develop new and complementary methods employing NHC-bound o-QDMlike nucleophiles.H erein, we report ad ecarboxylative transformation proceeding via an NHC-bound aza-o-QM intermediate to access enantioenriched dihydrobenzoxazin-4-ones (Scheme 1c). There have been significantly fewer developments employing oquinone methides (o-QMs) or aza-o-quinone methides (azao-QMs) as nucleophiles in NHC catalysis.Anotable recent advance by Chi employed salicylaldehydes in the presence of stoichiometric oxidant and base to generate an NHC-bound o-QM, which participated in an annulation with trifluoromethyl ketone electrophiles (Scheme 1b).…”

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confidence: 99%

Carbene‐Catalyzed Enantioselective Decarboxylative Annulations to Access Dihydrobenzoxazinones and Quinolones

et al. 2019

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Ad irect decarboxylative strategy for the generation of aza-o-quinone methides (aza-o-QMs) by N-heterocyclic carbene (NHC) catalysis has been discovered and explored. This process requires no stoichiometric additives in contrast with current approaches.A za-o-QMs react with trifluoromethyl ketones through af ormal [4+ +2] manifold to access highly enantioenriched dihydrobenzoxazin-4-one products, which can be converted to dihydroquinolones through an interesting stereoretentive aza-Petasis-Ferrier rearrangement sequence.C omplementary dispersion-corrected density functional theory (DFT) studies provided an accurate prediction of the reaction enantioselectivity and lend further insight to the origins of stereocontrol. Additionally,acomputed potential energy surface around the major transition structure suggests ac oncerted asynchronous mechanism for the formal annulation.Dihydrobenzoxazinones are an important class of N-heterocyclic compounds widely found in pharmaceutical molecules and natural products. [1] Thedihydrobenzoxazinone structural motif is also commonly used as an intermediate for the construction of many other heterocyclicc ompounds. [2] Consequently,n ew synthetic methods for the preparation of enantioenriched dihydrobenzoxazinones could fuel further studies on this versatile compound class.T odate,the majority of asymmetric methods for dihydrobenzoxazinone synthesis has focused on the dihydrobenzoxazin-2-one substructure, using av ariety of methods including formal [4+ +2] cycloaddition of o-benzoquinone imides with ketenes, [3] Rhcatalyzed conjugate addition, [4] Ir-catalyzed hydrogenation, [5] and Brønsted acid-catalyzed transfer hydrogenation. [6] The isomeric dihydrobenzoxazin-4-one substructure is also prevalent in both natural products and drug candidates.Although several straightforward racemic syntheses of dihydrobenzoxazin-4-ones have been reported, enantioselective methods for their construction remain underdeveloped to date. [7] N-heterocyclic carbene (NHC) catalysis has emerged as ap owerful strategy for the construction of carbo-and heterocyclic compounds over the past decade. [8] NHC-catalyzed Umpolung reactions employing enals have provided access to numerous divergent nucleophilic species,i ncluding acyl anion, enolate,and homoenolate equivalents.In2011, Ye demonstrated that NHC catalysis could also access dienolate equivalents. [9] Following Yesp reliminary disclosure,s everal reports of reactions employing "azolium dienolates" generated from various carbonyl precursors have emerged. [10] Particularly,t he NHC-catalyzed g-functionalization of aromatic substrates [11] has received attention due to the innovative deployment of unconventional o-quinodimethanes (o-QDMs) as substrates (Scheme 1a). [12] In 2013, Chi and co-workers initially reported NHCbound o-QDM intermediates could be generated from omethyl heteroaryl aldehydes [11a] and o-methyl heteroaryl esters. [11b] Following these studies,s everal approaches to extend this reactivity to carbocyclic aromatic systems have emerged...

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Carbene‐Catalyzed Enantioselective Decarboxylative Annulations to Access Dihydrobenzoxazinones and Quinolones

et al. 2019

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“…Lewis acids have been shown to be promising co‐catalysts that can enhance stereoselective control in multiple NHC‐catalytic reactions . We therefore examined Lewis acids as co‐catalysts (entries 5–7) and found that the addition of urea molecule G could succefully enhance the reaction er from 86:14 (entry 4) to 90:10 (entry 7). Organic or inorganic bases with strong basicities resulted in a decomposition of the N , O ‐acetal products (entry 8).…”

Section: Resultsmentioning

confidence: 99%

“…The carbon atoms were activated as either nucleophilic or electrophilic reactive centers. In 2017, Chi and co‐workers found that through the addition of a carbene to the aldehyde moiety of a 2‐hydroxyl benzaldehyde under oxidative conditions, the phenol oxygen atom could be activated for enantioselective reactions . This activation converted the acylazolium to an ortho ‐quinone methide ( o ‐QM) intermediate with the oxygen as the reactive center (Scheme b, left).…”

Section: Introductionmentioning

confidence: 99%

Carbene‐Catalyzed Enantioselective Aromatic N‐Nucleophilic Addition of Heteroarenes to Ketones

et al. 2019

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The aromatic nitrogen atoms of heteroarylaldehydes are activated by carbene catalysts to react with ketone electrophiles. Multi‐functionalized cyclic N,O‐acetal products are afforded in good to excellent yields and optical purities. Our reaction involves the formation of an unprecedented aza‐fulvene‐type acylazolium intermediate. A broad range of N‐heteroaromatic aldehydes and electron‐deficient ketone substrates works effectively in this transformation. Several of the chiral N,O‐acetal products afforded through this protocol exhibit excellent antibacterial activities against Ralstonia solanacearum (Rs) and are valuable in the development of novel agrichemicals for plant protection.

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“…When the reaction of 1 a and 2 a was performed in the absence of NHC pre‐catalyst 4 , the desired product 3 a was not formed indicating the role of NHC in this [6+2] annulation (Scheme , eq 6). Moreover, the acetal 10 a (likely formed by the N−H addition of 1 a to 2 a followed by intramolecular cyclization) was not observed under these conditions showing that the direct N−H addition of initially formed acylazolium and cyclization in a [3+2] pathway is not operating in this case . In addition, when the reaction was performed using N ‐Boc protected aldehyde 11 a , the product 3 a was not formed signifying the role of N−H moiety in forming the NHC‐bound cross‐conjugated aza‐trienolates (eq 7).…”

Section: Methodsmentioning

confidence: 99%

N‐Heterocyclic Carbene‐Catalyzed Formal [6+2] Annulation Reaction via Cross‐Conjugated Aza‐Trienolate Intermediates

Balanna

Madica

Mukherjee

et al. 2019

Chemistry A European J

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The diverser eactivity of N-heterocyclic carbenes (NHCs) in organocatalysis is due to the possibility of different modeso fa ction. Although NHC-bounde nolates and dienolates are known, the related NHC-bound cross-conjugated aza-trienolates remain elusive. Herein,w ed emonstrate the NHC-catalyzed formal [6+ +2] annulation of nitrogen-containing heterocyclic aldehydes with a,a,a-trifluoroacetophenones leadingt ot he formation of versatile pyrrolooxazolones (29 examples). The catalytically generated cross-conjugated aza-trienolates (aza-fulvene type) underwent smooth [6+ +2] annulation with electrophilic ketones to afford the product in moderate to good yields under mild conditions. Preliminary DFT studies on the mechanism are also provided.Scheme1.Generation and reaction of various NHC-enolates.

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A reaction mode of carbene-catalysed aryl aldehyde activation and induced phenol OH functionalization

Cited by 57 publications

References 53 publications

Carbene‐Catalyzed Enantioselective Decarboxylative Annulations to Access Dihydrobenzoxazinones and Quinolones

Carbene‐Catalyzed Enantioselective Decarboxylative Annulations to Access Dihydrobenzoxazinones and Quinolones

Carbene‐Catalyzed Enantioselective Aromatic N‐Nucleophilic Addition of Heteroarenes to Ketones

N‐Heterocyclic Carbene‐Catalyzed Formal [6+2] Annulation Reaction via Cross‐Conjugated Aza‐Trienolate Intermediates

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