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    This study introduces a deep graph learning model for computational toxicity prediction in drug discovery. The model enhances interpretability and addresses data challenges, improving decision-making in drug development.

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    Area of Science:

    • Computational chemistry
    • Machine learning in drug discovery
    • Toxicology

    Background:

    • Machine learning and deep learning have advanced computational toxicity prediction.
    • Challenges remain in handling data imbalance, missing labels, and model interpretability.
    • Accurate toxicity prediction is crucial for efficient drug discovery.

    Purpose of the Study:

    • To develop a novel substructure-based deep graph learning architecture for toxicity prediction.
    • To address data imbalance and missing labels in toxicity datasets.
    • To enhance the interpretability of toxicity prediction models.

    Main Methods:

    • Developed a deep graph learning architecture incorporating functional groups into molecular graphs.
    • Implemented strategies to manage missing labels and class imbalance.
    • Utilized functional group-based feature importance analysis for interpretability.

    Main Results:

    • The developed model demonstrated strong performance in toxicity prediction tasks.
    • The model effectively handled missing labels and class imbalance.
    • Functional group analysis provided insights into toxicity mechanisms and improved model interpretability.

    Conclusions:

    • The substructure-based deep graph learning model offers a reliable tool for toxicity prediction.
    • Enhanced model interpretability supports rational decision-making in drug development.
    • This approach lays the groundwork for developing advanced toxicity prediction systems.