Further Insight into the Castagnoli-Cushman-type Synthesis of 1,4,6-Trisubstituted 1,6-Dihydropyridin-2-(3H)-ones from 3-Arylglutaconic Acid Anhydrides

Azide-based in situ preparation of fused heterocyclic imines and their multicomponent reactions

Structurally diverse pyrroles, indoles and imidazoles bearing an N-ω-azidoalkyl moiety and an aldehyde or ketone function were prepared and successfully introduced into in situ imine generation via the intramolecular Staudinger/aza-Wittig tandem reaction. Reduction of the generated imines led to medicinally relevant nitrogen-containing fused heterocycles such as tetrahydropyrrolo[1,2-a]pyrazines and diazepines. Rare 8-membered hexahydropyrrolo[1,2-a][1,4]diazocine and 9-membered dihydro-4,8-(metheno)pyrrolo[1,2-a][1,4]diazacycloundecine were also synthesized. In addition, several one-pot transformations involving cyclic anhydrides or isocyanides (Castagnoli-Cushman, Ugi and azido-Ugi reactions) were added to the Staudinger/aza-Wittig sequence to afford novel fused polyheterocyclic delta-lactams, cyclic bisamides and tetrazoles in a multicomponent fashion. The synthesized compounds were profiled against human Trace Amine-Associated Receptor 1 (hTAAR1), and the best performing compound showed low nanomolar agonistic activity with an EC50 of 0.025 μM.

The Castagnoli–Cushman Reaction

Since the first reports of the reaction of imines and cyclic anhydrides by Castagnoli and Cushman, this procedure has been applied to the synthesis of a variety of lactams, some of them with important synthetic or biological interest. The scope of the reaction has been extended to the use of various Schiff bases and anhydrides as well as to different types of precursors for these reagents. In recent years, important advances have been made in understanding the mechanism of the reaction, which has historically been quite controversial. This has helped to develop reaction conditions that lead to pure diastereomers and even homochiral products. In addition, these mechanistic studies have also led to the development of new multicomponent versions of the Castagnoli–Cushman reaction that allow products with more diverse and complex molecular structures to be easily obtained.

One-Pot Sequence of Staudinger/aza-Wittig/Castagnoli-Cushman Reactions Provides Facile Access to Novel Natural-like Polycyclic Ring Systems

Realization of the one-pot Staudinger/aza-Wittig/Castagnoli-Cushman reaction sequence for a series of azido aldehydes and homophthalic anhydrides is described. The reaction proceeded at room temperature and delivered novel polyheterocycles related to the natural product realm in high yields and high diastereoselectivity. The methodology has been extended to three other cyclic anhydrides. These further unravel the potential of the Castagnoli-Cushman reaction in generating polyheterocyclic molecular scaffolds.

A General Approach to Spirocyclic Piperidines via Castagnoli–Cushman Chemistry

Unsaturated spirocyclic lactams stemming from a variant of the three-component Castagnoli–Cushman reaction successfully underwent hydrogenation to enable access to fully saturated spirocyclic lactams. The subsequent lactam reduction gave rise to 2-spiro piperidine building blocks. The latter can be further elaborated in compound libraries and, on their own, show propensity to activate trace amine-associated­ receptor 1 (TAAR1), an important target for CNS disease.

New reagent space and new scope for the Castagnoli–Cushman reaction of oximes and 3-arylglutaconic anhydrides

The Castagnoli–Cushman reaction of oximes, previously known only for homophthalic anhydride, was extended to 3-arylglutaconic anhydrides to produce a new family of cyclic hydroxamic acids from a significantly improved diversity of oxime substrates.

Synthesis of Nitroaromatic Compounds via Three-Component Ring Transformations

1-Methyl-3,5-dinitro-2-pyridone serves as an excellent substrate for nucleophilic-type ring transformation because of the electron deficiency and presence of a good leaving group. In this review, we focus on the three-component ring transformation (TCRT) of dinitropyridone involving a ketone and a nitrogen source. When dinitropyridone is allowed to react with a ketone in the presence of ammonia, TCRT proceeds to afford nitropyridines that are not easily produced by alternative procedures. Ammonium acetate can be used as a nitrogen source instead of ammonia to undergo the TCRT, leading to nitroanilines in addition to nitropyridines. In these reactions, dinitropyridone serves as a safe synthetic equivalent of unstable nitromalonaldehyde.