Johannes N. Lamhauge scite author profile

Nucleophile-nucleophile coupling is ac hallenging transformation in organic chemistry.Herein we present anovel umpolung strategy for a-functionalization of aldehydes with nucleophiles.T he strategy uses organocatalytic enamine activation and quinone-promoted oxidation to access O-bound quinol-intermediates that undergo nucleophilic substitution reactions.T hese quinol-intermediates react with different classes of nucleophiles.T he focus is on an unprecedented organocatalytic oxidative a-thiolation of aldehydes.T he reaction scope is demonstrated for ab road range of thiols and extended to chemoselective bioconjugation, and applicable to alarge variety of aldehydes.This strategy can also encompass organocatalytic enantioselective coupling of a-branched aldehydes with thiols forming quaternary thioethers.S tudies indicate as tereoselective formation of the intermediate followed by as tereospecific nucleophilic substitution reaction at aquaternary stereocenter,w ith inversion of configuration.

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An Asymmetric S_N2 Dynamic Kinetic Resolution

Rezayee

Enemærke

Linde

et al. 2021

J. Am. Chem. Soc.

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The SN2 reaction exhibits the classic Walden inversion, indicative of the stereospecific backside attack of the nucleophile on the stereogenic center. Observation of the inversion of the stereocenter provides evidence for an SN2-type displacement. However, this maxim is contingent on substitution proceeding on a discrete stereocenter. Here we report an SN2 reaction that leads to enantioenrichment of product despite starting from a racemic mixture of starting material. The enantioconvergent reaction proceeds through a dynamic Walden cycle, involving an equilibrating mixture of enantiomers, initiated by a chiral aminocatalyst and terminated by a stereoselective SN2 reaction at a tertiary carbon to provide a quaternary carbon stereocenter. A combination of computational, kinetic, and empirical studies elucidates the multifaceted role of the chiral organocatalyst to provide a model example of the Curtin–Hammett principle. These examples challenge the notion of enantioenriched products exclusively arising from predefined stereocenters when operating through an SN2 mechanism. Based on these principles, examples are included to highlight the generality of the mechanism. We anticipate the asymmetric SN2 dynamic kinetic resolution to be used for a variety of future reactions.

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Enantioselective α‐Etherification of Branched Aldehydes via an Oxidative Umpolung Strategy

et al. 2021

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Saturated carbonyl compounds are, via their enolate analogues, inherently nucleophilic at the α‐position. In the presence of a benzoquinone oxidant, the polarity of the α‐position of racemic α‐branched aldehydes is inverted, allowing for an enantioselective etherification using readily available oxygen‐based nucleophiles and an amino acid‐derived primary amine catalyst. A survey of benzoquinone oxidants identified p‐fluoranil and DDQ as suitable reaction partners. p‐Fluoranil enables the preparation of α‐aryloxylated aldehydes using phenol nucleophiles in up to 91 % ee, following either a one‐step or a two‐step, one‐pot protocol. DDQ allows for a more general etherification protocol in combination with a broader range of alcohol nucleophiles with enantioselectivities up to 95 % ee. Control experiments and isolation of a key quinol intermediate supports a mechanism proceeding via an SN2 dynamic‐kinetic resolution. These studies provide the basis for an aminocatalytic umpolung concept that allows for the asymmetric construction of tertiary ethers in the α‐position of aldehydes.

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Organocatalyzed Cross-Nucleophile Couplings: Umpolung of Catalytic Enamines

2022

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Conspectus The concept of umpolung, or polarity reversal, introduced by Seebach and Corey nearly half a century ago, ushered a new paradigm into synthetic chemistry. Novel connections were able to be forged among functional groups that were typically inaccessible. Conceptually, an umpolung reaction is identified only upon retrosynthetic analysis. Stoichiometric examples have served as a platform to develop and refine elegant methodologies into catalytic processes. The advent of these unconventional arrangements of canonical synthons into new points of diversity has expanded the repertoire of the synthetic toolbox. Within this context, asymmetric organocatalyzed methodologies remain rare, and there are even fewer aminocatalyzed variants. Recent years have witnessed a renaissance in α-functionalizations of aldehydes, specifically in the context of oxidative umpolung strategies. Unlike previous open-shell approaches, application of a quinone-based oxidant in conjunction with an aminocatalyst leads to a discrete, substitutionally labile quinone adduct. These have proven to be valuable building blocks toward polar reactivityauguring the advent of new avenues to construct tetrasubstituted tertiary stereocenters through the application of conventional nucleophiles to form C–C, C–N, C–O, and C–S bonds through an organocatalyzed cross-nucleophile coupling (organo-CNC) reaction. The resulting nonepimerizable stereocenter demonstrates high optical fidelity and provides a significant advancement in many applications that suffer from racemization, such as in vivo studies. This strategy harnesses a trifunctional aminocatalyst to promote an unusual SN2 reaction at a highly congested center. The selection of the quinone oxidant and nucleophile converges to a continuum of reactivity ranging from enantioselective oxidation to stereoselective substitution. A remarkable aspect of these developments is the identification of an asymmetric SN2 dynamic kinetic resolution (SN2-DKR) manifold. These organo-CNC reactions are highly modular and demonstrate complete stereocontrol from the catalyst with minimal influence from incoming chiral nucleophiles. Leveraging this facet, these technologies have been extended to peptidic bioconjugations bearing bio-orthogonoal linker molecules. This Account aims to highlight the progress, from an internal perspective, toward directing the initial result into established methodologies. Within this construct, the underlying principles of each reaction will be disseminated with specific content on inherent challenges and opportunity. Combined, these will serve as an instructive tool to stimulate applications in cross-disciplinary interfaces.

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Atroposelective brominations to access chiral biaryl scaffolds using high-valent Pd-catalysis

et al. 2023

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