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AttenGpKa: A Universal Predictor of Solvation Acidity Using Graph Neural Network and Molecular Topology

Hongle An, Xuyang Liu, Wensheng Cai, Xueguang Shao

2024Journal of Chemical Information and Modeling14 citationsDOI

Abstract

Rapid and accurate calculation of acid dissociation constant (p K a ) is crucial for designing chemical synthesis routes, optimizing catalysts, and predicting chemical behavior. Despite recent progress in machine learning, predicting solvation acidity, especially in nonaqueous solvents, remains challenging due to limited experimental data. This challenge arises from treating experimental values in different solvents as distinct data domains and modeling them separately. In this work, we treat both the solutes and solvents equally from a perspective of molecular topology and propose a highly universal framework called AttenGpKa for predicting solvation acidity. AttenGpKa is trained using 26,522 experimental p K a values from 60 pure and mixed solvents in the i BonD database. As a result, our model can simultaneously predict the p K a values of a compound in various solvents, including pure water, pure nonaqueous, and mixed solvents. AttenGpKa achieves universality by using graph neural networks and attention mechanisms to learn complex effects within solute and solvent molecules. Furthermore, encodings of both solute and solvent molecules are adaptively fused to simulate the influence of the solvent on acid dissociation. AttenGpKa demonstrates robust generalization in extensive validations. The interpretability studies further indicate that our model has effectively learnt electronic and solvent effects. A free-to-use software is provided to facilitate the use of AttenGpKa for p K a prediction.

Topics & Concepts

SolvationTopology (electrical circuits)Artificial neural networkGraphMolecular graphComputer scienceComputational chemistryChemistryMathematicsTheoretical computer scienceMachine learningOrganic chemistryMoleculeCombinatoricsComputational Drug Discovery MethodsMachine Learning in Materials ScienceMetabolomics and Mass Spectrometry Studies