Homoleptic lanthanide
complex Y[N(TMS)2]3 is an efficient homogeneous
catalyst for the hydroboration reduction
of secondary amides and tertiary amides to corresponding amines. A
series of amides containing different functional groups such as cyano,
nitro, and vinyl groups were found to be well-tolerated. This transformation
has also been nicely applied to the synthesis of indoles and piribedil.
Detailed isotopic labeling experiments, control experiments, and kinetic
studies provided cumulative evidence to elucidate the reaction mechanism.
We report herein a rare‐earth‐metal‐catalyzed insertion of a 2‐pyridine C(sp2)−H bond into an intramolecular unactivated vinyl bond. This reaction provides streamlined access to a range of azaindolines in moderate to excellent yields. The salient features of this reaction include simple and mild reaction conditions, 100% atom efficiency, and wide substrate scope. This methodology is also used to construct other nitrogen‐containing compounds such as naphthyridine derivatives. A plausible mechanism for the formation of azaindolines involving initial C−H bond activation by the lanthanide complex followed by C=C insertion into a Ln−C bond to form an alkyl lanthanide species that subsequently undergoes cyclization is proposed.
A novel palladium-catalyzed protocol for the synthesis of 9-arylacridines via tandem reaction of 2-(arylamino)benzonitrile with arylboronic acids in water has been developed with good functional group tolerance. The present synthetic route could be readily scaled up to gram quantity without difficulty. This methodology was further extended to the synthesis of a 4′-OH derivative, which showed estrogenic biological activity. Preliminary mechanistic experiments showed that this transformation involves a nucleophilic addition of aryl palladium species to the nitrile to generate an aryl ketone intermediate followed by an intramolecular Friedel−Crafts acylation and dehydration to acridines.
We herein report an efficient approach for the assembly of multiply substituted imidazoles and oxazoles in a singlestep manner. These transformations are based on a decarboxylation addition and annulation of readily accessible aromatic carboxylic acids and aliphatic nitriles and exhibit good functional group compatibility and a high step economy. The reaction is scalable, and asprepared products could be transformed into practical skeletons. Importantly, the late-stage derivatization of Momelotinib highlights the potential utility of this methodology.
Simple, commercially available iodine was successfully employed as a highly efficient and chemoselective catalyst for the oxidative annulation of β,γ-unsaturated hydrazones to produce 1,6-dihydropyridazines under mild conditions for the first time. Interestingly, when active β,γ-unsaturated hydrazone compounds containing electron-donating groups, such as furyl, thienyl, and cycloalkyl, were used, pyrroles were obtained. A gram-scale preparation experiment and further derivatization of pyridazines demonstrated the potential applicability of our synthesis method. Experimental studies and density functional theory calculations unveiled the origin of the chemoselectivity determining the formation of different products.
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