Integrating Chemical Language and Molecular Graph in Multimodal Fused Deep Learning for Drug Property Prediction
CoRR(2023)
摘要
Accurately predicting molecular properties is a challenging but essential
task in drug discovery. Recently, many mono-modal deep learning methods have
been successfully applied to molecular property prediction. However, the
inherent limitation of mono-modal learning arises from relying solely on one
modality of molecular representation, which restricts a comprehensive
understanding of drug molecules and hampers their resilience against data
noise. To overcome the limitations, we construct multimodal deep learning
models to cover different molecular representations. We convert drug molecules
into three molecular representations, SMILES-encoded vectors, ECFP
fingerprints, and molecular graphs. To process the modal information,
Transformer-Encoder, bi-directional gated recurrent units (BiGRU), and graph
convolutional network (GCN) are utilized for feature learning respectively,
which can enhance the model capability to acquire complementary and naturally
occurring bioinformatics information. We evaluated our triple-modal model on
six molecule datasets. Different from bi-modal learning models, we adopt five
fusion methods to capture the specific features and leverage the contribution
of each modal information better. Compared with mono-modal models, our
multimodal fused deep learning (MMFDL) models outperform single models in
accuracy, reliability, and resistance capability against noise. Moreover, we
demonstrate its generalization ability in the prediction of binding constants
for protein-ligand complex molecules in the refined set of PDBbind. The
advantage of the multimodal model lies in its ability to process diverse
sources of data using proper models and suitable fusion methods, which would
enhance the noise resistance of the model while obtaining data diversity.
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