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Hydration free energies from kernel-based machine learning: Compound-database bias

Clemens Rauer, Tristan Bereau

2020The Journal of Chemical Physics33 citationsDOIOpen Access PDF

Abstract

We consider the prediction of a basic thermodynamic property-hydration free energies-across a large subset of the chemical space of small organic molecules. Our in silico study is based on computer simulations at the atomistic level with implicit solvent. We report on a kernel-based machine learning approach that is inspired by recent work in learning electronic properties but differs in key aspects: The representation is averaged over several conformers to account for the statistical ensemble. We also include an atomic-decomposition ansatz, which offers significant added transferability compared to molecular learning. Finally, we explore the existence of severe biases from databases of experimental compounds. By performing a combination of dimensionality reduction and cross-learning models, we show that the rate of learning depends significantly on the breadth and variety of the training dataset. Our study highlights the dangers of fitting machine-learning models to databases of a narrow chemical range.

Topics & Concepts

Curse of dimensionalityTransferabilityRepresentation (politics)Chemical spaceArtificial intelligenceKey (lock)Variety (cybernetics)Computer scienceMachine learningDimensionality reductionStatistical physicsWork (physics)Space (punctuation)Statistical learningTraining setFeature (linguistics)Data miningBiological systemChemistryTheoretical computer scienceComponent (thermodynamics)Experimental dataReduction (mathematics)Molecular dynamicsChemical physicsThermodynamicsSolvationVariation (astronomy)MathematicsMaterials scienceStatistical modelBasis (linear algebra)Machine Learning in Materials ScienceComputational Drug Discovery MethodsGaussian Processes and Bayesian Inference
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