Litcius/Paper detail

A Machine Learning Approach to Model Interaction Effects: Development and Application to Alcohol Deoxyfluorination

A. Zuranski, Shivaani S. Gandhi, Abigail G. Doyle

2023Journal of the American Chemical Society20 citationsDOI

Abstract

The application of machine learning (ML) techniques to model high-throughput experimentation (HTE) datasets has seen a recent rise in popularity. Nevertheless, the ability to model the interplay between reaction components, known as interaction effects, with ML remains an outstanding challenge. Using a simulated HTE dataset, we find that the presence of irrelevant features poses a strong obstacle to learning interaction effects with common ML algorithms. To address this problem, we propose a two-part statistical modeling approach for HTE datasets: classical analysis of variance of the experiment to identify systematic effects that impact reaction yield across the experiment followed by regression of individual effects using chemistry-informed features. To illustrate this methodology, we use our previously published alcohol deoxyfluorination dataset comprising 740 reactions to build a compact, interpretable generalized additive model that accounts for each significant effect observed in the dataset. We achieve a sizeable performance boost compared to our previously published random forest model, reducing mean absolute error from 18 to 13% and root-mean-squared error from 22 to 17% on a newly generated validation set. Finally, we demonstrate that this approach can facilitate the generation of new mechanistic hypotheses, which, when probed experimentally, can lead to a deeper understanding of chemical reactivity.

Topics & Concepts

Machine learningRandom forestMean squared errorSet (abstract data type)Artificial intelligenceVariance (accounting)RegressionPopularityInteractionChemistryComputer scienceStatisticsMathematicsPsychologySocial psychologyProgramming languageAccountingBusinessMachine Learning in Materials ScienceComputational Drug Discovery MethodsMetabolomics and Mass Spectrometry Studies