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Automatic Chemical Design Using a Data-Driven Continuous Representation of Molecules

2018· article· en· 3 038 citations· W2529996553 sur OpenAlex· 10.1021/acscentsci.7b00572

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Résumé

We report a method to convert discrete representations of molecules to and from a multidimensional continuous representation. This model allows us to generate new molecules for efficient exploration and optimization through open-ended spaces of chemical compounds. A deep neural network was trained on hundreds of thousands of existing chemical structures to construct three coupled functions: an encoder, a decoder, and a predictor. The encoder converts the discrete representation of a molecule into a real-valued continuous vector, and the decoder converts these continuous vectors back to discrete molecular representations. The predictor estimates chemical properties from the latent continuous vector representation of the molecule. Continuous representations of molecules allow us to automatically generate novel chemical structures by performing simple operations in the latent space, such as decoding random vectors, perturbing known chemical structures, or interpolating between molecules. Continuous representations also allow the use of powerful gradient-based optimization to efficiently guide the search for optimized functional compounds. We demonstrate our method in the domain of drug-like molecules and also in a set of molecules with fewer that nine heavy atoms.

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La notice

Revue
ACS Central Science
Thématique
Machine Learning in Materials Science
Domaine
Materials Science
Établissements canadiens
Canadian Institute for Advanced ResearchUniversity of TorontoUniversity of New Brunswick
Organismes subventionnaires
Basic Energy SciencesDivision of Graduate EducationSamsungSamsung Advanced Institute of TechnologyFundación Rafael del PinoDivision of Information and Intelligent SystemsAlfred P. Sloan FoundationU.S. Department of EnergyNational Science Foundation
Mots-clés
Representation (politics)EncoderSet (abstract data type)Simple (philosophy)Chemical spaceContinuous modellingChemical processContinuous optimization
Résumé présent dans OpenAlex
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