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Synergy and Complementarity between Focused Machine Learning and Physics-Based Simulation in Affinity Prediction.

Ann E Cleves1, Stephen R Johnson2, Ajay N Jain3

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Combining physics-based simulation (FEP+) and machine learning (QuanSA) improves ligand affinity prediction. A hybrid model outperformed individual methods, enhancing both ranking and absolute pKi values across diverse targets.

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Area of Science:

  • Computational chemistry
  • Drug discovery

Background:

  • Ligand affinity prediction is crucial for drug discovery.
  • Physics-based simulation (FEP+) and machine learning (QuanSA) are established methods.
  • Assessing the complementarity of these approaches is key to optimizing prediction accuracy.

Purpose of the Study:

  • To evaluate the synergy between FEP+ and QuanSA for ligand affinity prediction.
  • To determine if a hybrid approach offers superior performance over individual methods.
  • To test the generalizability of this synergy across diverse biological targets.

Main Methods:

  • Applied FEP+ and QuanSA to predict activity of LFA-1 inhibitors.
  • Developed a hybrid model by averaging predictions from FEP+ and QuanSA.
  • Validated the hybrid model on two public FEP+ benchmarks with 16 diverse targets.

Main Results:

  • Both FEP+ and QuanSA provided accurate predictions within their domains.
  • The hybrid model significantly improved ranking and absolute pKi values compared to individual methods.
  • Accurate QuanSA models were derived using focused training data on relevant ligands.

Conclusions:

  • FEP+ and QuanSA are complementary for ligand affinity prediction.
  • A hybrid approach combining physics-based and machine learning methods enhances prediction accuracy.
  • Careful application of each method and hybrid strategies are recommended for optimal affinity prediction.