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Δ-Quantum machine-learning for medicinal chemistry

Kenneth Atz, Clemens Isert, Markus N. A. Böcker, José Jiménez-Luna, Gisbert Schneider

2022Physical Chemistry Chemical Physics56 citationsDOIOpen Access PDF

Abstract

Many molecular design tasks benefit from fast and accurate calculations of quantum-mechanical (QM) properties. However, the computational cost of QM methods applied to drug-like molecules currently renders large-scale applications of quantum chemistry challenging. Aiming to mitigate this problem, we developed DelFTa, an open-source toolbox for the prediction of electronic properties of drug-like molecules at the density functional (DFT) level of theory, using Δ-machine-learning. Δ-Learning corrects the prediction error (Δ) of a fast but inaccurate property calculation. DelFTa employs state-of-the-art three-dimensional message-passing neural networks trained on a large dataset of QM properties. It provides access to a wide array of quantum observables on the molecular, atomic and bond levels by predicting approximations to DFT values from a low-cost semiempirical baseline. Δ-Learning outperformed its direct-learning counterpart for most of the considered QM endpoints. The results suggest that predictions for non-covalent intra- and intermolecular interactions can be extrapolated to larger biomolecular systems. The software is fully open-sourced and features documented command-line and Python APIs.

Topics & Concepts

ToolboxPython (programming language)Intermolecular forceComputer scienceDensity functional theoryQuantumObservableQuantum chemistrySoftwareArtificial intelligenceDrug discoveryQuantum chemicalMachine learningChemistryComputational scienceStatistical physicsComputational chemistryMoleculeQuantum mechanicsPhysicsSupramolecular chemistryOrganic chemistryProgramming languageBiochemistryOperating systemComputational Drug Discovery MethodsMachine Learning in Materials ScienceProtein Structure and Dynamics
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