Exhaustive virtual screening is highly informative but often intractable against the expensive objective functions involved in modern drug discovery. This problem is exacerbated in combinatorial contexts such as multi-vector expansion, where molecular spaces can quickly become ultra-large. Here, we introduce Scalable Active Learning via Synthon Acquisition (SALSA): a simple algorithm applicable to multi-vector expansion which extends pool-based active learning to non-enumerable spaces by factoring modeling and acquisition over synthon or fragment choices. Through experiments on ligand- and structure-based objectives, we highlight SALSA's sample efficiency, and its ability to scale to spaces of trillions of compounds. Further, we demonstrate application toward multi-parameter objective design tasks on three protein targets - finding SALSA-generated molecules have comparable chemical property profiles to known bioactives, and exhibit greater diversity and higher scores over an industry-leading generative approach.
@article{arxiv.2505.12913,
title = {Active Learning on Synthons for Molecular Design},
author = {Tom George Grigg and Mason Burlage and Oliver Brook Scott and Adam Taouil and Dominique Sydow and Liam Wilbraham},
journal= {arXiv preprint arXiv:2505.12913},
year = {2025}
}
Comments
14 pages, 10 figures. Presented at ICLR 2025 GEM Workshop