English

CompleteRXN: Toward Completing Open Chemical Reaction Databases

Machine Learning 2026-05-29 v2 Chemical Physics

Abstract

Chemical reaction datasets such as USPTO suffer from substantial incompleteness, frequently missing byproducts, co-reactants, and stoichiometric coefficients. This limits their applicability and reliability in downstream applications. Here, we introduce CompleteRXN, a large-scale supervised benchmark for reaction completion under realistic missing-data conditions. We construct a dataset of aligned incomplete and atom-balanced reactions by mapping USPTO records to curated mechanistic reactions. We evaluate representative baselines, including a novel encoder-decoder reaction completion model with constrained decoding, the Constrained Reaction Balancer (CRB), and a recent algorithmic method, SynRBL. On our CompleteRXN benchmark, the CRB achieves high performance across splits of increasing difficulty, reaching 99.20% equivalence accuracy on the random split and 91.12% on the extreme out-of-distribution split. SynRBL produces many balanced and chemically plausible completions, but with lower accuracy on the benchmark test splits. Across all methods, performance degrades with increasing incompleteness. We observe a substantial drop when evaluating on reactions outside the benchmark (full uncurated USPTO), highlighting the gap between benchmark performance and practical robustness and motivating future work.

Cite

@article{arxiv.2605.00222,
  title  = {CompleteRXN: Toward Completing Open Chemical Reaction Databases},
  author = {Gabriel Vogel and Minouk Noordsij and Evgeny Pidko and Jana M. Weber},
  journal= {arXiv preprint arXiv:2605.00222},
  year   = {2026}
}
R2 v1 2026-07-01T12:44:31.154Z