Related papers: $\mathsf{G^2Retro}$ as a Two-Step Graph Generative Models for Retrosynthesis Prediction

$\mathsf{G^2Retro}$ as a Two-Step Graph Generative Models for Retrosynthesis Prediction

URL: http://arxiv.org/abs/2206.04882v3
Date: Mon, 5 Jun 2023 20:58:47 GMT
Title: $\mathsf{G^2Retro}$ as a Two-Step Graph Generative Models for Retrosynthesis Prediction
Authors: Ziqi Chen, Oluwatosin R. Ayinde, James R. Fuchs, Huan Sun, Xia Ning
Abstract summary: Retrosynthesis is a procedure where a target molecule is transformed into potential reactants. In this paper, we develop a generative framework $mathsfG2Retro$ for one-step retrosynthesis prediction.
Score: 21.905438801819027
License: http://creativecommons.org/licenses/by-nc-sa/4.0/
Abstract: Retrosynthesis is a procedure where a target molecule is transformed into potential reactants and thus the synthesis routes can be identified. Recently, computational approaches have been developed to accelerate the design of synthesis routes. In this paper, we develop a generative framework $\mathsf{G^2Retro}$ for one-step retrosynthesis prediction. $\mathsf{G^2Retro}$ imitates the reversed logic of synthetic reactions. It first predicts the reaction centers in the target molecules (products), identifies the synthons needed to assemble the products, and transforms these synthons into reactants. $\mathsf{G^2Retro}$ defines a comprehensive set of reaction center types, and learns from the molecular graphs of the products to predict potential reaction centers. To complete synthons into reactants, $\mathsf{G^2Retro}$ considers all the involved synthon structures and the product structures to identify the optimal completion paths, and accordingly attaches small substructures sequentially to the synthons. Here we show that $\mathsf{G^2Retro}$ is able to better predict the reactants for given products in the benchmark dataset than the state-of-the-art methods.

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