Energy-based View of Retrosynthesis
Ruoxi Sun, Hanjun Dai, Li Li, Steven Kearnes, Bo Dai
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ReproduceAbstract
Retrosynthesis -- the process of identifying a set of reactants to synthesize a target molecule -- is of vital importance to material design and drug discovery. Existing machine learning approaches based on language models and graph neural networks have achieved encouraging results. In this paper, we propose a framework that unifies sequence- and graph-based methods as energy-based models (EBMs) with different energy functions. This unified perspective provides critical insights about EBM variants through a comprehensive assessment of performance. Additionally, we present a novel dual variant within the framework that performs consistent training over Bayesian forward- and backward-prediction by constraining the agreement between the two directions. This model improves state-of-the-art performance by 9.6% for template-free approaches where the reaction type is unknown.
Tasks
Benchmark Results
| Dataset | Model | Metric | Claimed | Verified | Status |
|---|---|---|---|---|---|
| USPTO-50k | Dual-TF (reaction class as prior) | Top-1 accuracy | 65.7 | — | Unverified |
| USPTO-50k | Dual-TF (reaction class unknown) | Top-1 accuracy | 53.6 | — | Unverified |