Retro-Fallback: Retrosynthetic Planning in an Uncertain World
Abstract
Retrosynthesis is the task of proposing a series of chemical reactions to create a desired molecule from simpler, buyable molecules. While previous works have proposed algorithms to find optimal solutions for a range of metrics (e.g. shortest, lowest-cost), these works generally overlook the fact that we have imperfect knowledge of the space of possible reactions, meaning plans created by the algorithm may not work in a laboratory. In this paper we propose a novel formulation of retrosynthesis in terms of stochastic processes to account for this uncertainty. We then propose a novel greedy algorithm called retro-fallback which maximizes the probability that at least one synthesis plan can be executed in the lab. Using in-silico benchmarks we demonstrate that retro-fallback generally produces better sets of synthesis plans than the popular MCTS and retro* algorithms. We encourage the reader to view the full version of this paper at https://arxiv.org/abs/2310.09270.
Cite
Text
Tripp et al. "Retro-Fallback: Retrosynthetic Planning in an Uncertain World." NeurIPS 2023 Workshops: AI4Science, 2023.Markdown
[Tripp et al. "Retro-Fallback: Retrosynthetic Planning in an Uncertain World." NeurIPS 2023 Workshops: AI4Science, 2023.](https://mlanthology.org/neuripsw/2023/tripp2023neuripsw-retrofallback/)BibTeX
@inproceedings{tripp2023neuripsw-retrofallback,
title = {{Retro-Fallback: Retrosynthetic Planning in an Uncertain World}},
author = {Tripp, Austin and Maziarz, Krzysztof and Lewis, Sarah and Segler, Marwin and Hernández-Lobato, José Miguel},
booktitle = {NeurIPS 2023 Workshops: AI4Science},
year = {2023},
url = {https://mlanthology.org/neuripsw/2023/tripp2023neuripsw-retrofallback/}
}