Reaction-based machine learning representations for predicting the enantioselectivity of organocatalysts.
Simone GallaratiRaimon FabregatMilagros MedinaSinjini BhattacharjeeMatthew D WodrichClémence CorminbœufPublished in: Chemical science (2021)
Hundreds of catalytic methods are developed each year to meet the demand for high-purity chiral compounds. The computational design of enantioselective organocatalysts remains a significant challenge, as catalysts are typically discovered through experimental screening. Recent advances in combining quantum chemical computations and machine learning (ML) hold great potential to propel the next leap forward in asymmetric catalysis. Within the context of quantum chemical machine learning (QML, or atomistic ML), the ML representations used to encode the three-dimensional structure of molecules and evaluate their similarity cannot easily capture the subtle energy differences that govern enantioselectivity. Here, we present a general strategy for improving molecular representations within an atomistic machine learning model to predict the DFT-computed enantiomeric excess of asymmetric propargylation organocatalysts solely from the structure of catalytic cycle intermediates. Mean absolute errors as low as 0.25 kcal mol-1 were achieved in predictions of the activation energy with respect to DFT computations. By virtue of its design, this strategy is generalisable to other ML models, to experimental data and to any catalytic asymmetric reaction, enabling the rapid screening of structurally diverse organocatalysts from available structural information.
Keyphrases
- machine learning
- big data
- working memory
- artificial intelligence
- crystal structure
- molecular dynamics
- molecular dynamics simulations
- density functional theory
- molecular docking
- deep learning
- patient safety
- healthcare
- emergency department
- solid state
- computed tomography
- magnetic resonance imaging
- capillary electrophoresis
- highly efficient
- risk assessment
- climate change
- quality improvement
- loop mediated isothermal amplification
- diffusion weighted imaging