Quantum and Classical Graph Convolutional Neural Networks for Protein Ligand Dissociation Constant Prediction
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CC-BY-4.0
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This study developed a GCN+GRU model that incorporates temporal information and uses variational quantum circuits for compression to improve protein-ligand dissociation constant prediction accuracy and reduce model size.
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Abstract
How long a drug stays bound to its target - the residence time - is now recognized as a stronger in vivo efficacy driver than binding affinity alone. Yet current machine learning (ML) models for dissociation kinetics (koff) ignore two critical sources of structure information: (1) the change in protein–ligand geometry across time, and (2) the ability to represent complex spatial interactions with fewer parameters. We extend a state-of -the -art spatial GNN for protein–ligand complexes with two innovations. First, we introduce a 2–timestep GCN+GRU model that learns structure changes before and after short molecular dynamics simulations. Second, we compress the model head using variational quantum circuits, preserving expressivity while removing 66% of parameters. On the full PDBbind-koff-2020 benchmark, temporal integration improves predictive accuracy, and quantum compression matches the full classical model’s accuracy at a fraction of its size. Our results show that time and quantum structure are underexplored, high-leverage axes for advancing kinetic ML models used in drug design.
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- europepmc
- last seen: 2026-05-20T01:45:00.602351+00:00
- unpaywall
- last seen: 2026-05-30T02:00:01.510937+00:00
License: CC-BY-4.0