MicroCycle:
An
Integrated and Automated Platform to
Accelerate Drug Discovery

Brocklehurst, Cara E.; Altmann, Eva; Bon, Corentin; Davis, Holly; Dunstan, David; Ertl, Peter; Ginsburg-Moraff, Carol; Grob, Jonathan; Gosling, Daniel J.; Lapointe, Guillaume; Marziale, Alexander N.; Mues, Heinrich; Palmieri, Marco; Racine, Sophie; Robinson, Richard I.; Springer, Clayton; Tan, Kian; Ulmer, William; Wyler, René

doi:10.1021/acs.jmedchem.3c02029.s001

jm3c02029_si_001.pdf (2.83 MB)

MicroCycle: An Integrated and Automated Platform to Accelerate Drug Discovery

journal contribution

posted on 2024-01-25, 16:15 authored by Cara E. Brocklehurst, Eva Altmann, Corentin Bon, Holly Davis, David Dunstan, Peter Ertl, Carol Ginsburg-Moraff, Jonathan Grob, Daniel J. Gosling, Guillaume Lapointe, Alexander N. Marziale, Heinrich Mues, Marco Palmieri, Sophie Racine, Richard I. Robinson, Clayton Springer, Kian Tan, William Ulmer, René Wyler

We herein describe the development and application of a modular technology platform which incorporates recent advances in plate-based microscale chemistry, automated purification, in situ quantification, and robotic liquid handling to enable rapid access to high-quality chemical matter already formatted for assays. In using microscale chemistry and thus consuming minimal chemical matter, the platform is not only efficient but also follows green chemistry principles. By reorienting existing high-throughput assay technology, the platform can generate a full package of relevant data on each set of compounds in every learning cycle. The multiparameter exploration of chemical and property space is hereby driven by active learning models. The enhanced compound optimization process is generating knowledge for drug discovery projects in a time frame never before possible.