A 2018 joint pharma report identified organic synthesis as one of the major bottlenecks in drug discovery today. In the highly competitive discovery environments, only fast-to-synthesise molecules are targeted, which has led to only a small portion of the chemical shape space being explored and been partly blamed for the recent low success rates in new drug development.
Over the last two decades a new type of synthetic approach called C-H activation has been proposed to address this challenge. In this approach, molecules can be built in a more straightforward and flexible manner, by ‘simply’ breaking (ie activating) C-H bonds in precursors and installing the desired functionality or molecular scaffold in place of the hydrogen. However, the field of C‒H activation is significantly behind in achieving this aim: most biologically active molecules contain several polar and/or delicate functionalities (‘real world’ molecules), whereas most C‒H activation methods use harsh conditions, incompatible with delicate groups, and catalysts that tend to poison in the presence of polar groups.
This project aims at developing a new class of tools, based on ruthenium catalysts, to allow C-H activation in complex molecules, under mild conditions while avoiding catalyst poisoning. These catalysts will be expanded to be able to replace the hydrogen in chosen C-H bonds with a variety of substituents, thus maximizing its impact in streamlining the synthesis of pharmaceuticals, agrochemicals and other related compounds. This in turn will lead to a better capacity for synthesising and exploring the properties of novel molecules as well as affording more sustainable processes.