English

MolecularRNN: Generating realistic molecular graphs with optimized properties

Machine Learning 2019-06-03 v1 Artificial Intelligence Molecular Networks Quantitative Methods Machine Learning

Abstract

Designing new molecules with a set of predefined properties is a core problem in modern drug discovery and development. There is a growing need for de-novo design methods that would address this problem. We present MolecularRNN, the graph recurrent generative model for molecular structures. Our model generates diverse realistic molecular graphs after likelihood pretraining on a big database of molecules. We perform an analysis of our pretrained models on large-scale generated datasets of 1 million samples. Further, the model is tuned with policy gradient algorithm, provided a critic that estimates the reward for the property of interest. We show a significant distribution shift to the desired range for lipophilicity, drug-likeness, and melting point outperforming state-of-the-art works. With the use of rejection sampling based on valency constraints, our model yields 100% validity. Moreover, we show that invalid molecules provide a rich signal to the model through the use of structure penalty in our reinforcement learning pipeline.

Keywords

Cite

@article{arxiv.1905.13372,
  title  = {MolecularRNN: Generating realistic molecular graphs with optimized properties},
  author = {Mariya Popova and Mykhailo Shvets and Junier Oliva and Olexandr Isayev},
  journal= {arXiv preprint arXiv:1905.13372},
  year   = {2019}
}
R2 v1 2026-06-23T09:34:21.502Z