Modular, automated synthesis of spirocyclic tetrahydronaphthyridines from primary alkylamines

Spirocyclic tetrahydronaphthyridines (THNs) are valuable scaffolds for drug discovery campaigns, but access to this 3D chemical space is hampered by a lack of modular and scalable synthetic methods. We hereby report an automated, continuous flow synthesis of α-alkylated and spirocyclic 1,2,3,4-tetrahydro-1,8-naphthyridines (“1,8-THNs”), in addition to their regioisomeric 1,6-THN analogues, from abundant primary amine feedstocks. An annulative disconnection approach based on photoredox-catalysed hydroaminoalkylation (HAA) of halogenated vinylpyridines is sequenced in combination with intramolecular S N Ar N -arylation. To access the remaining 1,7- and 1,5-THN isomers, a photoredox-catalysed HAA step is telescoped with a palladium-catalysed C–N bond formation. Altogether, this provides a highly modular access to four isomeric THN cores from a common set of unprotected primary amine starting materials, using the same bond disconnections. The simplifying power of the methodology is illustrated by a concise synthesis of the spirocyclic THN core of Pfizer’s MC4R antagonist PF-07258669. Spirocyclic tetrahydronaphthyridines (THNs) are valuable structural motifs in medicinal chemistry, but the modular and scalable synthesis of this specific motif remains challenging. Here, the authors develop an automated and continuous flow synthesis of 1,8-THN and 1,6-THN analogues based on photoredox-catalysed hydroaminoalkylation, demonstrating the concise synthesis of the spirocyclic THN core of Pfizer’s MC4R antagonist PF-07258669.