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Papers/On Improving Graph Neural Networks for QSAR by Pre-training on Extended-Connectivity Fingerprints
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On Improving Graph Neural Networks for QSAR by Pre-training on Extended-Connectivity Fingerprints

May 11, 2026

arXiv
Abstract

Molecular Graph Neural Networks (GNNs) are increasingly common in drug discovery, particularly for Quantitative Structure-Activity Relationship (QSAR) studies; yet, their superiority compared to classical molecular featurisation approaches is disputed. We report a general strategy for improving GNNs for QSAR by pre-training to predict Extended-Connectivity Fingerprints (ECFP). We validate our approach with statistical tests and challenging out-of-distribution (OOD) splits. Across five out of six Biogen benchmarks, we observed a statistically significant improvement in standard performance metrics over all evaluated baselines when using ECFP pre-trained GNNs. However, for more heterogeneous datasets and more complex endpoints, such as binding affinity prediction, pre-trained GNNs underperformed in OOD settings. Importantly, we investigated the impact of substructure-level data leakage during pre-training on downstream performance. While we identified scenarios where pre-training on ECFPs was less effective, our findings show that ECFP-based pre-training can enhance downstream OOD performance on a diverse set of practically relevant QSAR tasks.

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Authors
Sam Money-Kyrle, Markus Dablander, Thierry Hanser, Stephane Werner, Charlotte M. Deane, Garrett M. Morris
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arXiv:2605.10722