Room-Temperature Decarboxylative Alkynylation of Carboxylic Acids Using Photoredox Catalysis and EBX Reagents

Alkynes are used as building blocks in synthetic and medicinal chemistry, chemical biology, and materials science. Therefore, efficient methods for their synthesis are the subject of intensive research. Herein, we report the direct synthesis of alkynes from readily available carboxylic acids at room temperature under visible-light irradiation. The combination of an iridium photocatalyst with ethynylbenziodoxolone (EBX) reagents allowed the decarboxylative alkynylation of carboxylic acids in good yields under mild conditions. The method could be applied to silyl-, aryl-, and alkyl- substituted alkynes. It was particularly successful in the case of alpha-amino and alpha-oxo acids derived from biomass.

Photoredox-Catalyzed Decarboxylation for the Transfer of Alkynes and Nitriles Using Hypervalent Iodine Reagents

Franck Le Vaillant

Aliphatic alkynes and nitriles are privileged motifs in organic chemistry. Therefore, alkynes and nitriles have played a central role for the exploration and development of novel strategies to forge C-C bonds in efficient manner. They are broadly used as versatile building blocks for applications in every fields of chemistry, from pharmaceuticals to material sciences. Alkynes are also of paramount importance in chemical biology for labelling experiments due to their bio orthogonality. In this context, radical chemistry provides endless alternatives to nucleophilic and electrophilic alkynylation and cyanation reactions. For decades, organic chemists have designed and improved the structure of alkynylating reagents in order to enhance the efficiency of group transfer process. Methods enabling alkynylation and cyanation of alkyl radicals have emerged and while providing useful tools, they set the basis for further improvements. Notably, the formation of alkyl radicals is limited to harsh conditions using peroxides, elevated temperature and radical initiators. To overcome these major limitations, photoredox catalysis has emerged as a powerful tool for the generation of alkyl radicals under ambient conditions. The combination of photocatalysts and alkynylating reagents allowed the photoredox-catalyzed alkynylation of organoboron trifluoroborates salt and N-phtalimide esters. In this regard, the goal of my PhD was first to extend the photoredox catalyzed alkynylation to carboxylic acids. Indeed, carboxylic acids are broadly available from biomass, and widely occurring in drugs and fine chemicals, thus making them attractive starting materials. Their conversion to alkynes would provide efficient disconnections for the construction of Csp3-Csp, and find useful applications in chemical biology. Ethynyl Benziodoxolone (EBX) reagents, CsOBz and iridium photocatalysts were identified as a promising combination for the development of this novel transformation, in which silyl, aryl and alkyl substituted alkynes were transferred. ï¡ïamino, ï¡ïoxy and non-heteroatom stabilized radicals could be alkynylated in good to excellent yields upon visible light irradiation. This strategy was next applied to the decarboxylative cyanation of carboxylic acids. In that regard, Cyano Benziodoxolone CBX was introduced for the first time in photoredox-catalyzed cyanation. The combination of CBX, CsOBz and the same iridium photocatalyst allowed the smooth conversion of amino and oxy acids to their corresponding nitriles, and this novel method was applied to the synthesis of important intermediates in the synthesis of APIs. During scope investigations, hydantoins were isolated as side products. This background reaction was further optimized as a novel and efficient synthesis of chiral hydantoins starting from amino acids and CBX. Finally, investigations of the reaction mechanisms of the photoredox-catalyzed decarboxylations revealed that the cyanation followed a divergent mechanism compared to alkynylation. A additional redox step between CBX and ï¡-amino radical allows the generation of cyanide and iminium, which upon recombination affords the nitrile product. Then, the second goal of my PhD was to implement the photoredox mediated alkynylation and cyanation to other starting materials. In this regard, the use of carboxylic acids as starting materials to initiate photoredox catalyzed radical fragmentations was an appealing strategy.

EPFL2019

Ring-Opening Reactions of Aminocyclopropanes and Aminocyclobutanes

Mingming Wang

Nitrogen-containing compounds are an important class of molecules in medicinal chemistry, chemical biology, biochemistry, material sciences or environmental sciences. Organic nitrogen occurs in many forms, ranging from small building blocks such as urea, amino acids, nucleotides, to complex natural products, drug molecules, proteins, nucleic acids, among others. The transformation of easily-accessed nitrogen-containing building blocks into more complex nitrogen-containing structures is therefore important for the synthesis of bioactive compounds or functional materials. Interested in donor-acceptor aminocyclopropanes and aminocyclobutanes, we first developed a Lewis-acid catalyzed formal [4+1] cycloaddition of donor-acceptor aminocyclobutanes with isocyanides, which resulted in the formation of cyclopentene-1,2-diamines. We then attempted to develop a formal [3+2] cycloaddition of donor-acceptor aminocyclopropanes with electron-deficient alkenes, which was mechanistically inspired by the Morita-Baylis-Hillman reaction. Apart from the donor-acceptor system, we were also attracted by simple aminocyclopropanes without electron-withdrawing group at vicinal position. We anticipated that the incorporation of cyclopropylamine into carboxylic-containing compounds followed by ring opening functionalization reactions could be used for the synthesis of more complex products. Therefore, we first disclosed an oxidative ring-opening strategy to transform acyl, sulfonyl or carbamate protected aminocyclopropanes into 1,3-dielectrophilic carbon intermediates bearing a halide atom (Br, I) and a N,O-acetal. Replacing the alkoxy group of the N,O-acetal was achieved under acidic conditions via an elimination-addition pathway, while substitution of the halides by nucleophiles was done under basic conditions via a SN2 pathway, generating a wide range of 1,3-difunctionalized propylamines. Based on the transformation described above, we further discovered an efficient synthesis of 4-amino thiochromans starting from simple aminocyclopropanes and thiophenols through a formal [3+3] annulation reaction. Next, we developed an oxidative ring-opening strategy to transform cyclopropylamides and cyclobutylamides into fluorinated imines. The imines can be isolated in their more stable hemiaminal form, with the fluorine atom installed selectively at the terminal position. Both cheap benzophenone with UV A light or organic and inorganic dyes with blue light could be used as photoredox catalysts to promote this process. Various fluorinated amines were then obtained by nucleophilic attack on the hemiaminals in one pot, giving access to a broad range of useful building blocks for medicinal chemistry. Finally, we turned our attention to the synthesis of diamines, which are essential building blocks for the synthesis of agrochemicals, drugs and organic materials, yet their synthesis remains challenging, as both nitrogen moieties need to be differentiated and diverse substitution patterns (1,2-, 1,3 or 1,4) are required. We described a new strategy giving access to 1,2-, 1,3- and 1,4- amido azides as orthogonally protected diamines based on the nitrogen-directed diazidation of alkenes, cyclopropanes and cyclobutanes.Other unsuccessful efforts over the last four years have also been described, together with some preliminary results of ring-opening cyanation and arylation reactions.

EPFL2022

Gold-Catalyzed Alkynylation: Acetylene-Transfer instead of Functionalization

Jonathan Brand, Yifan Li, Jérôme Waser

Over the last fifteen years, gold has been raised from the status of an inert noble metal to one of the most-often-used catalysts in synthetic chemistry. The functionalization of the triple bond of alkynes has been especially successful in this respect. In contrast, gold-catalyzed alkynylation reactions only began to emerge in 2007. Since then, three different approaches have been successfully used for this transformation. 1) Gold nanoparticles have been shown to promote catalytic cycles based on the oxidative arylation of aryl halides to give a palladium-free Sonogashira reaction. 2) The use of benziodoxol(on)e hypervalent iodine compounds as oxidative alkynylation reagents has allowed the CH functionalization of electron-rich heterocycles under mild conditions with a very broad functional-group tolerance. 3) The use of iodobenzene acetate or Selectfluor as an external oxidant has led to the first alkynylation methods based on direct CH/CH coupling reactions. In only six years, gold-catalyzed alkynylation methods have grown from non-existent to useful synthetic procedures for the synthesis of structurally diverse alkynes. Considering that acetylenes are among the most-important building blocks for applications in synthetic chemistry, chemical biology, and materials science, there is tremendous potential for the further development of gold-catalyzed alkynylation reactions in the future.