Veeranjaneyulu Lanke scite author profile

A highly regioselective functionalization of indole at the C-4 position by employing an aldehyde functional group as a directing group, and Ru as a catalyst, under mild reaction conditions (open flask) has been uncovered. This strategy to synthesize 4-substituted indoles is important, as this class of privileged molecules serves as a precursor for ergot alkaloids and related heterocyclic compounds.

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Rhodium(iii)-catalyzed C–H activation at the C4-position of indole: switchable hydroarylation and oxidative Heck-type reactions of maleimides

Sherikar

Kapanaiah

Lanke

et al. 2018

Chem. Commun.

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A Rh(iii)-catalyzed C-H activation of indole at the C4-position leading to novel and switchable functionalization has been reported by employing a weakly co-ordinating COCF3 group as a directing group. An additive plays an important role in switching the selectivity between 1,4-addition products and Heck-type products. An acid additive led to the formation of 1,4-addition products whereas a base additive promotes the formation of Heck-type products. Deuteration studies and control experiments were helpful to propose the mechanism.

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Nucleophilic Substitution at Quaternary Carbon Stereocenters

Lanke

Marek

2020

J. Am. Chem. Soc.

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Cyclopropyl carbinol derivatives undergo a regio- and stereoselective nucleophilic substitution at the quaternary carbon center, with pure inversion of configuration, to provide the acyclic products as a single diastereomer. The selectivity of the substitution is attributed to the existence of a cyclobutonium species, reacting at the most substituted carbon center. Diastereomerically pure and enantiomerically enriched tertiary alkyl bromide, chloride, ester, and fluoride could therefore be easily prepared in only three catalystic steps from commercially available alkynes.

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Electronic Nature of Ketone Directing Group as a Key To Control C-2 vs C-4 Alkenylation of Indoles

2016

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A novel mode of achieving site selectivity between C-2 and C-4 positions in the indole framework by altering the property of the ketone directing group is disclosed. Methyl ketone, as directing group, furnishes exclusively C-2 alkenylated product, whereas trifluoromethyl ketone changes the selectivity to C-4, indicating that the electronic nature of the directing group controls the unusual choice between a 5-membered and a 6-membered metallacycle. The screening of other carbonyl-derived directing groups reveals that strong and weak directing groups exhibit opposite selectivity. Experimental controls and deuteration experiments lend support to the proposed mechanism.

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Ru (II)-Catalyzed C–H Activation: Ketone-Directed Novel 1,4-Addition of Ortho C–H Bond to Maleimides

2015

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A 1,4-addition with the nucleophilic center generated at the ortho carbon atom of an aromatic ketone in the presence of the highly reactive α-C-H bond, using a directing group strategy, is presented. The reaction yields pharmaceutically useful 3-arylated succinimide derivatives. In order to gain understanding of this redox neutral reaction, despite the presence of copper acetate, and to substantiate the lack of Heck-type products, DFT calculations have been carried out.

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