Nature Communications (Feb 2024)

An integrated self-optimizing programmable chemical synthesis and reaction engine

  • Artem I. Leonov,
  • Alexander J. S. Hammer,
  • Slawomir Lach,
  • S. Hessam M. Mehr,
  • Dario Caramelli,
  • Davide Angelone,
  • Aamir Khan,
  • Steven O’Sullivan,
  • Matthew Craven,
  • Liam Wilbraham,
  • Leroy Cronin

DOI
https://doi.org/10.1038/s41467-024-45444-3
Journal volume & issue
Vol. 15, no. 1
pp. 1 – 10

Abstract

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Abstract Robotic platforms for chemistry are developing rapidly but most systems are not currently able to adapt to changing circumstances in real-time. We present a dynamically programmable system capable of making, optimizing, and discovering new molecules which utilizes seven sensors that continuously monitor the reaction. By developing a dynamic programming language, we demonstrate the 10-fold scale-up of a highly exothermic oxidation reaction, end point detection, as well as detecting critical hardware failures. We also show how the use of in-line spectroscopy such as HPLC, Raman, and NMR can be used for closed-loop optimization of reactions, exemplified using Van Leusen oxazole synthesis, a four-component Ugi condensation and manganese-catalysed epoxidation reactions, as well as two previously unreported reactions, discovered from a selected chemical space, providing up to 50% yield improvement over 25–50 iterations. Finally, we demonstrate an experimental pipeline to explore a trifluoromethylations reaction space, that discovers new molecules.