Deep Molecular Dreaming: Inverse machine learning for de-novo molecular design and interpretability with surjective representations

Computer-based de-novo design of functional molecules is one of the most prominent challenges in cheminformatics today. As a result, generative and evolutionary inverse designs from the field of artificial intelligence have emerged at a rapid pace, with aims to optimize molecules for a particular chemical property. These models 'indirectly' explore the chemical space; by learning latent spaces, policies, distributions or by applying mutations on populations of molecules. However, the recent development of the SELFIES string representation of molecules, a surjective alternative to SMILES, have made possible other potential techniques. Based on SELFIES, we therefore propose PASITHEA, a direct gradient-based molecule optimization that applies inceptionism techniques from computer vision. PASITHEA exploits the use of gradients by directly reversing the learning process of a neural network, which is trained to predict real-valued chemical properties. Effectively, this forms an inverse regression model, which is capable of generating molecular variants optimized for a certain property. Although our results are preliminary, we observe a shift in distribution of a chosen property during inverse-training, a clear indication of PASITHEA's viability. A striking property of inceptionism is that we can directly probe the model's understanding of the chemical space it was trained on. We expect that extending PASITHEA to larger datasets, molecules and more complex properties will lead to advances in the design of new functional molecules as well as the interpretation and explanation of machine learning models.

[1]  Beyond generative models: superfast traversal, optimization, novelty, exploration and discovery (STONED) algorithm for molecules using SELFIES† , 2021, Chemical science.

[2]  Andrew Zisserman,et al.  Very Deep Convolutional Networks for Large-Scale Image Recognition , 2014, ICLR.

[3]  Li Li,et al.  Optimization of Molecules via Deep Reinforcement Learning , 2018, Scientific Reports.

[4]  Alán Aspuru-Guzik,et al.  Objective-Reinforced Generative Adversarial Networks (ORGAN) for Sequence Generation Models , 2017, ArXiv.

[5]  Jan H. Jensen,et al.  A graph-based genetic algorithm and generative model/Monte Carlo tree search for the exploration of chemical space , 2018, Chemical science.

[6]  Alexander Mordvintsev,et al.  Inceptionism: Going Deeper into Neural Networks , 2015 .

[7]  Cao Xiao,et al.  Constrained Generation of Semantically Valid Graphs via Regularizing Variational Autoencoders , 2018, NeurIPS.

[8]  James J. P. Stewart,et al.  Optimization of parameters for semiempirical methods VI: more modifications to the NDDO approximations and re-optimization of parameters , 2012, Journal of Molecular Modeling.

[9]  Jan H. Jensen,et al.  Chemical Space Exploration: How Genetic Algorithms Find the Needle in the Haystack , 2020 .

[10]  Jordan M. Malof,et al.  Neural-adjoint method for the inverse design of all-dielectric metasurfaces. , 2020, Optics express.

[11]  Jure Leskovec,et al.  Graph Convolutional Policy Network for Goal-Directed Molecular Graph Generation , 2018, NeurIPS.

[12]  Alán Aspuru-Guzik,et al.  Augmenting Genetic Algorithms with Deep Neural Networks for Exploring the Chemical Space , 2020, ICLR.

[13]  Assessing methods and obstacles in chemical space exploration , 2020 .

[14]  Isaac Tamblyn,et al.  Scientific intuition inspired by machine learning-generated hypotheses , 2021, Mach. Learn. Sci. Technol..

[15]  Pavlo O. Dral,et al.  Quantum chemistry structures and properties of 134 kilo molecules , 2014, Scientific Data.

[16]  Alán Aspuru-Guzik,et al.  Inverse molecular design using machine learning: Generative models for matter engineering , 2018, Science.

[17]  Alán Aspuru-Guzik,et al.  Automatic Chemical Design Using a Data-Driven Continuous Representation of Molecules , 2016, ACS central science.

[18]  Nicola De Cao,et al.  MolGAN: An implicit generative model for small molecular graphs , 2018, ArXiv.

[19]  Ribana Roscher,et al.  Explainable Machine Learning for Scientific Insights and Discoveries , 2019, IEEE Access.

[20]  Regina Barzilay,et al.  Junction Tree Variational Autoencoder for Molecular Graph Generation , 2018, ICML.

[21]  Jordan M. Malof,et al.  Benchmarking deep inverse models over time, and the neural-adjoint method , 2020, NeurIPS.

[22]  Alán Aspuru-Guzik,et al.  Self-referencing embedded strings (SELFIES): A 100% robust molecular string representation , 2019, Mach. Learn. Sci. Technol..

[23]  Alireza Seif,et al.  Machine learning the thermodynamic arrow of time , 2019, Nature Physics.

[24]  Andrea Vedaldi,et al.  Understanding deep image representations by inverting them , 2014, 2015 IEEE Conference on Computer Vision and Pattern Recognition (CVPR).

[25]  C. Lipinski Lead- and drug-like compounds: the rule-of-five revolution. , 2004, Drug discovery today. Technologies.

[26]  Renato Renner,et al.  Discovering physical concepts with neural networks , 2018, Physical review letters.

[27]  Amina Adadi,et al.  Peeking Inside the Black-Box: A Survey on Explainable Artificial Intelligence (XAI) , 2018, IEEE Access.

[28]  Jan H Jensen A graph-based genetic algorithm and generative model/Monte Carlo tree search for the exploration of chemical space† †Electronic supplementary information (ESI) available: The codes used in this study can be found on GitHub: github.com/jensengroup/GB-GA/tree/v0.0 and github.com/jensengroup/GB-GM/tree , 2019, Chemical science.

[29]  Connor W. Coley Defining and Exploring Chemical Spaces , 2020, Trends in Chemistry.