Palladium-catalyzed asymmetric allylic 4-pyridinylation via electroreductive substitution reaction

Ding, Weijie; Li, Mengfan; Fan, Jinkun; Xu, Cheng

doi:10.1038/s41467-022-33452-0

Cited by 13 publications

(10 citation statements)

References 69 publications

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“…Therefore, paired electrolysis can be considered as the gold standard for two desirable progressions on both electrodes [ 106 , 107 ]. On the other hand, there should be more advances made in asymmetric electrochemical radical reductive transformation [ 86 , 108 ]. We hope that this Review will inspire further developments in this exciting area of electrochemistry.…”

Section: Discussionmentioning

confidence: 99%

“…This method was successfully applied to the synthesis of β-pyridine thioester. It should be mentioned that very recently Cheng group reported an electroreductively enantioselective Pd-catalyzed allylic 4-pyridinylation [ 86 ]. This method successfully employed the chiral η 3 allyl Pd complex to capture the persistent radical via radical rebound.…”

Section: Electrochemical Reductionmentioning

confidence: 99%

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Electroreductively Induced Radicals for Organic Synthesis

Xiang

He²,

Qian³

et al. 2023

Molecules

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Organic electrochemistry has attracted tremendous interest within the novel sustainable methodologies that have not only reduced the undesired byproducts, but also utilized cleaner and renewable energy sources. Particularly, oxidative electrochemistry has gained major attention. On the contrary, reductive electrolysis remains an underexplored research direction. In this context, we discuss advances in transition-metal-free cathodically generated radicals for selective organic transformations since 2016. We highlight the electroreductive reaction of alkyl radicals, aryl radicals, acyl radicals, silyl radicals, fluorosulfonyl radicals and trifluoromethoxyl radicals.

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Section: Discussionmentioning

confidence: 99%

Section: Electrochemical Reductionmentioning

confidence: 99%

Electroreductively Induced Radicals for Organic Synthesis

Xiang

He²,

Qian³

et al. 2023

Molecules

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“…[150] More recently, the Cheng group described an asymmetric allyl pyridinylation of a range of allyl acetates catalyzed by electrochemistry and a chiral Pd(II)-diphosphine ligand complex to yield the corresponding allyl pyridinylation product with moderate to high levels of enantioselectivity (Scheme 47). [151] The authors suggested that the catalytic cycle commenced with the reduction of PdCl 2 -diphosphine ligand complex (L*PdCl 2 ) to the [L*Pd 0 ] active species 47A. Subsequently, Oxidative addition would happen between cinnamyl acetate 121 and 47A leading to allyl Pd II intermediate 47B, which would undergo cathodic reduction to generate Pd species 47C.…”

Section: Electro-catalyzed Decyanative Arylation Enabled By Csp3à X (...mentioning

confidence: 99%

Radical Decyanations of Unactivated Carbon‐CN Bonds: Recent Achievements and Mechanistic Studies

Huang

Chen

2023

Adv Synth Catal

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Decyanation is an important process in the synthesis of aromatic molecules in the studies of pharmaceutical research, medical and materials sciences. In late‐stage modifications of privileged carbo/heterocyclic scaffolds, radical‐type decyanation techniques have been devised to date. As a result, the chemistry of cyano‐involved conversions, a hotly debated subject over the past few decades, has advanced significantly. The cyano group (CN), on the other hand, has rarely been acknowledged as a good reaction site due to its thermodynamic robustness. The most recent advancements in catalytic radical decyanation protocols that CN behaved as a leaving group has made are surveyed in this article. Following the introduction of a number of different reaction modes, the catalytic reactions that are used to activate the C−CN bonds are primarily categorized, and the text herein are divided into three groups: (1) photo‐catalyzed decyanation transformations, (2) electro‐catalyzed decyanation transformations, and (3) transition‐metal‐catalyzed or metal‐free decyanation transformations. With an emphasis on the catalytic systems and synthetic applications in C−CN bond activation, this review will provide the readers with an overview of decyanation chemistry in radical reactions.

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“…In 2022, Cheng and co-workers also combined palladium catalysis with electrochemistry, developing a system in which palladium complexes act as electron mediators and transitionmetal catalysts in turn throughout the reaction (Scheme 6e). 19 4cyanopyridine was used as pyridine raw material to construct 4allyl pyridine, which represents the first case of asymmetric allyl 4-pyridylation catalyzed by 4-cyanopyridine under electrochemical conditions. Here, 4-cyanopyridine will not be directly reduced on the electrode surface, but uses palladium as an electron reduction assistant.…”

Section: Palladium Catalysismentioning

confidence: 99%

Asymmetric Organic Electrochemistry Catalyzed by Transition Metals

Zheng¹,

Tao²,

Ma³

et al. 2022

Synthesis

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Asymmetric catalysis is one of the most important areas of organic synthetic chemistry. In recent years, with the revival of organic electrochemistry, scientists have begun to try to combine asymmetric catalysis with electrochemistry to build valuable chiral molecules. In this review, we focus on examples of organic electrochemistry catalyzed by transition metals. According to the classification of the catalyst’s interaction with the substrate, we can divide them into two categories: 1) transition-metal catalysts as chiral Lewis acids; 2) transition-metal catalysts that construct chiral molecules by interacting with substrates through oxidative addition/reductive elimination.

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Palladium-catalyzed asymmetric allylic 4-pyridinylation via electroreductive substitution reaction

Cited by 13 publications

References 69 publications

Electroreductively Induced Radicals for Organic Synthesis

Electroreductively Induced Radicals for Organic Synthesis

Radical Decyanations of Unactivated Carbon‐CN Bonds: Recent Achievements and Mechanistic Studies

Asymmetric Organic Electrochemistry Catalyzed by Transition Metals

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