22990-19-8Relevant articles and documents
Light-Promoted Dearomative Cross-Coupling of Heteroarenium Salts and Aryl Iodides via Nickel Catalysis
Nallagonda, Rajender,Musaev, Djamaladdin G.,Karimov, Rashad R.
, p. 1818 - 1829 (2022/02/07)
Partially saturated nitrogen heterocycles are versatile building blocks for the preparation of other nitrogen heterocycles. For example, dihydropyridines can be converted to pyridines, tetrahydropyridines, and piperidines through oxidation, reduction, and functionalization reactions, respectively. Dearomatization of heteroarenes is an attractive approach for the synthesis of partially saturated heterocycles such as dihydropyridines due to the wide availability of heteroarenes. Significant research efforts have been dedicated to the addition of nucleophiles to various heteroarenium salts in this direction using organoboron or organometallic reagents. The availability of organoboron and organometallic coupling partners has been an important limitation to this chemistry. Direct coupling of electrophiles with heteroareniums could significantly improve the scope of these dearomatization reactions due to the wider availability of electrophiles compared to nucleophiles such as organoboron and organometallic reagents. Herein, we report the coupling of aryl iodides with pyridinium and related heteroarenium salts catalyzed by Ni/bpp and an Ir photocatalyst using Zn as a terminal reductant. This methodology tolerates a wide range of functional groups and allows the coupling of aryl and heteroaryl iodides, thus significantly expanding the scope of nitrogen heterocycle scaffolds that could be prepared through dearomatization of heteroarenes. The reaction products have been further functionalized to prepare various nitrogen heterocycles. Initial mechanistic studies indicate that the reaction described herein goes through a unique mechanism involving dimers of dihydroheteroarenes.
Low-Temperature Nickel-Catalyzed C?N Cross-Coupling via Kinetic Resolution Enabled by a Bulky and Flexible Chiral N-Heterocyclic Carbene Ligand
Hong, Xin,Shi, Shi-Liang,Wang, Zi-Chao,Xie, Pei-Pei,Xu, Youjun
supporting information, p. 16077 - 16084 (2021/06/17)
The transition-metal-catalyzed C?N cross-coupling has revolutionized the construction of amines. Despite the innovations of multiple generations of ligands to modulate the reactivity of the metal center, ligands for the low-temperature enantioselective amination of aryl halides remain a coveted target of catalyst engineering. Designs that promote one elementary reaction often create bottlenecks at other steps. We here report an unprecedented low-temperature (as low as ?50 °C), enantioselective Ni-catalyzed C?N cross-coupling of aryl chlorides with sterically hindered secondary amines via a kinetic resolution process (s factor up to >300). A bulky yet flexible chiral N-heterocyclic carbene (NHC) ligand is leveraged to drive both oxidative addition and reductive elimination with low barriers and control the enantioselectivity. Computational studies indicate that the rotations of multiple σ-bonds on the C2-symmetric chiral ligand adapt to the changing needs of catalytic processes. We expect this design would be widely applicable to diverse transition states to achieve other challenging metal-catalyzed asymmetric cross-coupling reactions.
Discovery of quinuclidine modulators of cellular progranulin
Burnett, Duane A.,Chen, Angela Y.-P.,Koenig, Gerhard,Lanter, James C.,Williamson, Toni,Blain, Jean-Fran?ois
, (2021/06/30)
Phenotypic screening of an annotated small molecule library identified the quinuclidine tetrahydroisoquinoline solifenacin (1) as a robust enhancer of progranulin secretion with single digit micromolar potency in a murine microglial (BV-2) cell line. Subsequent SAR development led to the identification of 29 with a 38-fold decrease in muscarinic receptor antagonist activity and a 10-fold improvement in BV-2 potency.