EvoMol: a flexible and interpretable evolutionary algorithm for unbiased de novo molecular generation

Abstract: The objective of this work is to design a molecular generator capable of exploring known as well as unfamiliar areas of the chemical space. Our method must be flexible to adapt to very different problems. Therefore, it has to be able to work with or without the influence of prior data and knowledge. Moreover, regardless of the success, it should be as interpretable as possible to allow for diagnosis and improvement. We propose here a new open source generation method using an evolutionary algorithm to sequenti… Show more

“…All top-12 molecules in Figure 4 have low S SAS values, less than 2.5, suggesting that they are readily synthesizable. It is noticeable that, even though we optimized S mQED in this study, the S QED values of the top-12 molecules are identical or comparable to the best reported values obtained from the sole optimization of S QED [25]. In conclusion, the above results indicate that molecule optimization of S mQED using MolFinder successfully generated a set of molecules with good druglikeness and synthetic accessibility simultaneously.…”

“…In addition to recent ML-based approaches, various genetic algorithm (GA)-based molecular property optimization algorithms have been developed [25,26,27,28,29,30,31,32,33]. The main advantage of GA-based algorithms is that they do not require a large amount of molecule data relevant to a given optimization task because they search novel molecules in a combinatorial and stochastic way.…”

“…Most existing GA-based molecular optimization algorithms are based on the graph representation of a molecule. In recent studies, they showed competitive, sometimes better, performance compared to ML-based methods in generating novel molecules with desired properties [26,28,29,25]. A GA-based method using the graph representation requires careful design of crossover and/or mutation operations of graphs, which may bias the direction and extension of chemical space search.…”

MolFinder: An Evolutionary Algorithm for the Global Optimization of Molecular Properties and the Extensive Exploration of Chemical Space Using SMILES

“…All top-12 molecules in Figure 4 have low S SAS values, less than 2.5, suggesting that they are readily synthesizable. It is noticeable that, even though we optimized S mQED in this study, the S QED values of the top-12 molecules are identical or comparable to the best reported values obtained from the sole optimization of S QED [25]. In conclusion, the above results indicate that molecule optimization of S mQED using MolFinder successfully generated a set of molecules with good druglikeness and synthetic accessibility simultaneously.…”

“…In addition to recent ML-based approaches, various genetic algorithm (GA)-based molecular property optimization algorithms have been developed [25,26,27,28,29,30,31,32,33]. The main advantage of GA-based algorithms is that they do not require a large amount of molecule data relevant to a given optimization task because they search novel molecules in a combinatorial and stochastic way.…”

“…Most existing GA-based molecular optimization algorithms are based on the graph representation of a molecule. In recent studies, they showed competitive, sometimes better, performance compared to ML-based methods in generating novel molecules with desired properties [26,28,29,25]. A GA-based method using the graph representation requires careful design of crossover and/or mutation operations of graphs, which may bias the direction and extension of chemical space search.…”

MolFinder: An Evolutionary Algorithm for the Global Optimization of Molecular Properties and the Extensive Exploration of Chemical Space Using SMILES

MolFinder: an evolutionary algorithm for the global optimization of molecular properties and the extensive exploration of chemical space using SMILES