The last decade has witnessed a burgeoning of new methods for the enantioselective vicinal difunctionalization of alkenes initiated by electrophilic sulfenyl group transfer. The addition of sulfenium ions to alkenes results in the generation of chiral, non‐racemic thiiranium ions. These highly reactive intermediates are susceptible to attack by a myriad of nucleophiles in a stereospecific ring‐opening event to afford anti 1,2‐sulfenofunctionalized products. The practical application of sulfenium ion transfer has been enabled by advances in the field of Lewis base catalysis. This Review will chronicle the initial discovery and characterization of thiiranium ion intermediates followed by the determination of their configurational stability and the challenges of developing enantioselective variants. Once the framework for the reactivity and stability of thiiranium ions has been established, a critical analysis of pioneering studies will be presented. Finally, a comprehensive discussion of modern synthetic applications will be categorized around the type of nucleophile employed for sulfenofunctionalization.
A new general concept for α,β‐unsaturated acyl ammonium catalysis is reported that uses p‐nitrophenoxide release from an α,β‐unsaturated p‐nitrophenyl ester substrate to facilitate catalyst turnover. This method was used for the enantioselective isothiourea‐catalyzed Michael addition of nitroalkanes to α,β‐unsaturated p‐nitrophenyl esters in generally good yield and with excellent enantioselectivity (27 examples, up to 79 % yield, 99:1 er). Mechanistic studies identified rapid and reversible catalyst acylation by the α,β‐unsaturated p‐nitrophenyl ester, and a recently reported variable‐time normalization kinetic analysis method was used to delineate the complex reaction kinetics.
A catalytic, enantio‐, and diastereoselective formation of sulfenyl acetals bearing multiple stereogenic centers is reported. Alkenyl aldehydes undergo a chiral thiiranium ion initiated cascade starting with intramolecular capture by a formyl group and termination by capture with HFIP solvent. This method provides a one‐pot synthesis of dihydropyran and 1,3‐disubstituted isochroman acetals in good to excellent yield and with high levels of diastereo‐ (up to >99:1 dr) and enantiocontrol (up to 99:1 er).
Azabicyclo[2.1.1]hexanes (aza-BCHs) and bicyclo[1.1.1]pentanes
(BCPs) have emerged as attractive classes of sp
3-rich cores for replacing flat, aromatic groups with metabolically
resistant, three-dimensional frameworks in drug scaffolds. Strategies
to directly convert, or “scaffold hop”, between these
bioisosteric subclasses through single-atom skeletal editing would
enable efficient interpolation within this valuable chemical space.
Herein, we describe a strategy to “scaffold hop” between
aza-BCH and BCP cores through a nitrogen-deleting skeletal edit. Photochemical
[2+2] cycloadditions, used to prepare multifunctionalized aza-BCH
frameworks, are coupled with a subsequent deamination step to afford
bridge-functionalized BCPs, for which few synthetic solutions currently
exist. The modular sequence provides access to various privileged
bridged bicycles of pharmaceutical relevance.
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