Improved Substrate Scope in the Potassium Hexacyanoferrate(II)-Based Cyanation for the Synthesis of Benzonitriles and Their Heterocyclic Analogues.

The use of Pd(DPEPhos)Cl2 (P26) as a catalyst for the formation of benzonitriles and their heterocyclic analogues provides excellent complementarity to existing catalysts, allowing highly electron-deficient heterocyclic aryl halides to be efficiently converted to the corresponding nitriles using K4[Fe(CN)6]) as cyanide source. This catalyst significantly enhances the scope of this reaction to include a number of substrates that are highly relevant for pharmaceutical and agrochemical applications. Importantly, not only does this cyanation method employ a nontoxic cyanide source, simple semiquantitative testing suggests that, unlike many other methods, no free cyanide is present in the reaction mixture or during a variety of potential workups, thus improving the safety aspects of this method from initial setup through to product isolation. Finally, developing and testing a series of convenient cyanation kits has allowed facile application and broader adoption of this method in our laboratories.

Sulfonyl-morpholino-pyrimidines: SAR and development of a novel class of selective mTOR kinase inhibitor.

High throughput screening to identify inhibitors of the mTOR kinase revealed sulfonyl-morpholino-pyrimidine 1 as an attractive start point. The compound displayed good physicochemical properties and selectivity over related kinases such as PI3Kα. Library preparation of related analogs allowed the establishment of additional SAR understanding and in particular the requirement for a key hydrogen bond donor motif at the 4-position of the phenyl ring in compounds such as indole 19. Isosteric replacement of the indole functionality led to the identification of urea compounds such as 32 that show good levels of mTOR inhibition in both enzyme and cellular assays.

Regioselective synthesis of N-aminoisoindolones and mono-N- and di-N,N'-substituted phthalazones utilizing hydrazine nucleophiles in a palladium-catalyzed three-component cascade process.

A palladium-catalyzed three-component cascade process for the synthesis of isoindolone and phthalazone derivatives is reported. The cascade process involves carbonylation of an aryl iodide/Michael acceptor to give an acylpalladium species which is intercepted by a hydrazine nucleophile. Intramolecular Michael addition follows to give either N-aminoisoindolones or mono- N- and di-N,N'-phthalazones depending on whether a monosubstituted or 1,2-disubstituted hydrazine nucleophile is used.