Litcius/Paper detail

Representation of molecular structures with persistent homology for machine learning applications in chemistry

Jacob Townsend, Cassie Putman Micucci, John H. Hymel, Vasileios Maroulas, Konstantinos D. Vogiatzis

2020Nature Communications129 citationsDOIOpen Access PDF

Abstract

Abstract Machine learning and high-throughput computational screening have been valuable tools in accelerated first-principles screening for the discovery of the next generation of functionalized molecules and materials. The application of machine learning for chemical applications requires the conversion of molecular structures to a machine-readable format known as a molecular representation. The choice of such representations impacts the performance and outcomes of chemical machine learning methods. Herein, we present a new concise molecular representation derived from persistent homology, an applied branch of mathematics. We have demonstrated its applicability in a high-throughput computational screening of a large molecular database (GDB-9) with more than 133,000 organic molecules. Our target is to identify novel molecules that selectively interact with CO 2 . The methodology and performance of the novel molecular fingerprinting method is presented and the new chemically-driven persistence image representation is used to screen the GDB-9 database to suggest molecules and/or functional groups with enhanced properties.

Topics & Concepts

Representation (politics)Persistent homologyMolecular machineComputer scienceMoleculeVirtual screeningHomology (biology)Drug discoveryMachine learningArtificial intelligenceChemistryNanotechnologyBioinformaticsMaterials scienceBiologyAlgorithmAmino acidBiochemistryPolitical scienceOrganic chemistryPoliticsLawComputational Drug Discovery MethodsMachine Learning in Materials ScienceTopological and Geometric Data Analysis