Unknown

Dataset Information

0

Molecular de-novo design through deep reinforcement learning.


ABSTRACT: This work introduces a method to tune a sequence-based generative model for molecular de novo design that through augmented episodic likelihood can learn to generate structures with certain specified desirable properties. We demonstrate how this model can execute a range of tasks such as generating analogues to a query structure and generating compounds predicted to be active against a biological target. As a proof of principle, the model is first trained to generate molecules that do not contain sulphur. As a second example, the model is trained to generate analogues to the drug Celecoxib, a technique that could be used for scaffold hopping or library expansion starting from a single molecule. Finally, when tuning the model towards generating compounds predicted to be active against the dopamine receptor type 2, the model generates structures of which more than 95% are predicted to be active, including experimentally confirmed actives that have not been included in either the generative model nor the activity prediction model. Graphical abstract .

SUBMITTER: Olivecrona M 

PROVIDER: S-EPMC5583141 | biostudies-other | 2017 Sep

REPOSITORIES: biostudies-other

altmetric image

Publications

Molecular de-novo design through deep reinforcement learning.

Olivecrona Marcus M   Blaschke Thomas T   Engkvist Ola O   Chen Hongming H  

Journal of cheminformatics 20170904 1


This work introduces a method to tune a sequence-based generative model for molecular de novo design that through augmented episodic likelihood can learn to generate structures with certain specified desirable properties. We demonstrate how this model can execute a range of tasks such as generating analogues to a query structure and generating compounds predicted to be active against a biological target. As a proof of principle, the model is first trained to generate molecules that do not contai  ...[more]