Exploiting the Different Nucleophilicity of the Isocyano Group: A Strategy for the Isocyanide Functionalization.

By exploiting the different nucleophilicity of aromatic and aliphatic isocyanides, we selectively react aliphatic isocyano groups while preserving aromatic ones in Passerini and Ugi multicomponent reactions. This simple approach allows the synthesis of α-acyloxy carboxamides or α-acylamino carboxamides possessing one or two isocyanide groups, which are challenging to achieve through traditional formylation and dehydration protocols. These analogues have the potential to serve as valuable building blocks with diverse applications.

Each Interruption is an Opportunity: Novel Synthetic Strategies Explored Through Interrupted Click Reactions.

The particular and unique mechanism of the copper-catalyzed reaction between azides and alkynes (CuAAC) has not only allowed for the efficient synthesis of 1,2,3-trisubstituted 1,4-triazoles in excellent yields and under mild conditions, becoming the quintessential click reaction, but it has also enabled the straightforward formation of a metallocycle intermediate, the copper triazolyl. This, under suitable reaction conditions able to suppress its protonolysis, can be used either for the creation of new bicyclic triazolyl structures or for the generation of novel three or four-component reactions. The aim of this review is to rationalize and unify all these transformations, which are collectively referred to as "interrupted click reactions".

Domino synthesis of 5-aminoimidazoles from Strecker multicomponent adducts via ytterbium-promoted isocyanide insertion/5-exo-dig cyclization.

A new Lewis acid promoted domino isocyanide insertion/5-exo-dig cyclization of readily available Strecker 3-component adducts to 4-substituted 5-aminoimidazole derivatives is herein reported. Despite their potential as relevant heterocyclic scaffolds in medicinal chemistry programs, this class of compounds is still underrepresented, with current synthetic strategies poorly efficient in terms of timing and yields. To this end, we show how the exploitation of unconventional reactivities of isocyanides, promoted by ytterbium-triflate, could represent a key resource to enable a fast and easy access to such an unexplored area of the chemical space.

Visible-Light Photoredox Catalysis in Water.

The use of water in organic synthesis draws attention to its green chemistry features and its unique ability to unveil unconventional reactivities. Herein, literature about the use of water as a reaction medium under visible-light photocatalytic conditions is summarized in order to highlight challenges and opportunities. Accordingly, this Synopsis has been divided into four different sections focused on (1) the unconventional role of water in photocatalytic reactions, (2) in-/on-water reactions, (3) water-soluble photocatalysts, and (4) photomicellar catalytic systems.

Isocyanide-Based Multicomponent Reactions Promoted by Visible Light Photoredox Catalysis.

Isocyanide-based multicomponent reactions claim a one century-old history of flourishing developments. On the other hand, the enormous impact of recent progresses in visible light photocatalysis has boosted the identification of new straightforward and green approaches to both new and known chemical entities. In this context, the application of visible light photocatalytic conditions to multicomponent processes has been promoting key stimulating advancements. Spanning from radical-polar crossover pathways, to photoinduced and self-catalyzed transformations, to reactions involving the generation of imidoyl radical species, the present literature analysis would provide a general and critical overview about the potentialities and challenges of exploiting isocyanides in visible light photocatalytic multicomponent reactions.

Isocyanides in med chem: A scaffold hopping approach for the identification of novel 4-isocyanophenylamides as potent antibacterial agents against methicillin-resistant Staphylococcusaureus.

We describe the rational use of the neglected isocyano moiety as pharmacophoric group for the design of novel 4-isocyanophenylamides as antibacterial agents. This class of novel compounds showed to be highly effective against methicillin resistant Staphylococcus aureus strains. In particular, from an extensive screening, we identified compound 42 as lead compound. It has shown a potent antimicrobial activity, an additive effect with most antibiotics currently in use, the ability not to induce the formation of resistant strains after ten passages, and the ability to block the biofilm formation. A nontoxic profile on mammalian cells and a proper metabolic stability on human liver microsome complete the picture of this new weapon against methicillin resistant Staphylococcus aureus infections.

Expanding the Chemical Space of Drug-like Passerini Compounds: Can α-Acyloxy Carboxamides Be Considered Hard Drugs?

With their three points of diversity, α-acyloxy carboxamides, which are accessible with the Passerini reaction, provide heterogeneity for the preparation of libraries of putative active agents or intermediates used for the formation of more complex structures. If on the one hand the presence of a hydrolyzable ester function has been exploited to design both prodrugs and soft drugs, on the other hand medicinal chemists are reluctant to use this skeleton to prepare hard drugs. Herein we investigated whether the stability of the ester could be controlled, leading to the formation of hydrolytically stable α-acyloxy carboxamides. When the group directly attached to the ester moiety (R3) is an ortho-substituted or ortho,ortho'-disubstituted aromatic ring, α-acyloxy carboxamides are stable. In human liver but not in rodents, due to the different expression of esterases, the ester function is also stable toward hydrolysis when the R1 group is a bulky substituent regardless of the nature of the R3 substituent.

Medicinal Chemistry of Isocyanides.

In eons of evolution, isocyanides carved out a niche in the ecological systems probably thanks to their metal coordinating properties. In 1859 the first isocyanide was synthesized by humans and in 1950 the first natural isocyanide was discovered. Now, at the beginning of XXI century, hundreds of isocyanides have been isolated both in prokaryotes and eukaryotes and thousands have been synthesized in the laboratory. For some of them their ecological role is known, and their potent biological activity as antibacterial, antifungal, antimalarial, antifouling, and antitumoral compounds has been described. Notwithstanding, the isocyanides have not gained a good reputation among medicinal chemists who have erroneously considered them either too reactive or metabolically unstable, and this has restricted their main use to technical applications as ligands in coordination chemistry. The aim of this review is therefore to show the richness in biological activity of the isocyanide-containing molecules, to support the idea of using the isocyanide functional group as an unconventional pharmacophore especially useful as a metal coordinating warhead. The unhidden hope is to convince the skeptical medicinal chemists of the isocyanide potential in many areas of drug discovery and considering them in the design of future drugs.