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Human-in-the-loop active learning for goal-oriented molecule generation.

Yasmine Nahal1,2, Janosch Menke3, Julien Martinelli4

  • 1Department of Computer Science, Aalto University, 02150, Espoo, Finland. yasmine.nahal@aalto.fi.

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Summary
This summary is machine-generated.

This study introduces an adaptive approach using active learning and human feedback to improve machine learning models for drug discovery. The method refines property predictors, leading to more accurate molecule generation and better drug-likeness, overcoming limitations of existing data.

Keywords:
Active learningGoal-oriented molecule generationHuman-in-the-loopInteractive algorithmsMachine learning

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Area of Science:

  • Computational chemistry and cheminformatics.
  • Artificial intelligence in drug discovery.
  • Machine learning for predictive modeling.

Background:

  • Machine learning (ML) models, including quantitative structure-property relationship (QSPR) and structure-activity relationship (QSAR) predictors, are crucial for accelerating drug discovery by predicting molecular properties.
  • Current ML predictors often lack generalizability due to limited training data, leading to the generation of molecules with inflated predicted properties that fail experimental validation.
  • Generative AI agents guided by these predictors can explore chemical spaces but are susceptible to these limitations, producing molecules with poor real-world performance.

Purpose of the Study:

  • To develop an adaptive framework that refines ML property predictors for more effective goal-oriented molecule generation.
  • To enhance the accuracy and reliability of ML-guided drug discovery by integrating active learning (AL) and iterative human feedback.
  • To improve the generation of drug-like molecules with desirable properties by addressing the generalization issues of current predictors.

Main Methods:

  • Integration of active learning (AL) with iterative feedback mechanisms to refine ML property predictors.
  • Utilization of the Expected Predictive Information Gain (EPIG) criterion for selecting molecules to reduce predictive uncertainty.
  • Leveraging human experts as an oracle for cost-effective feedback to augment limited training data and refine predictors.
  • Empirical evaluation through simulated and real human-in-the-loop experiments.

Main Results:

  • The proposed approach successfully refines property predictors, aligning them better with oracle assessments.
  • Demonstrated improvement in the accuracy of predicted molecular properties.
  • Observed enhanced drug-likeness and other practical characteristics (e.g., synthetic accessibility) among the top-ranking generated molecules.
  • The framework shows robustness to noise in human feedback.

Conclusions:

  • The developed adaptable framework effectively integrates active learning and human expertise to refine property predictors for goal-oriented molecule generation.
  • This approach enhances the reliability of generative AI in drug discovery by ensuring generated molecules satisfy predicted profiles and score well on oracle models.
  • Prioritizes practical drug development considerations, balancing chemical space exploration with exploitation of existing knowledge and similarity.