Multi-task learning framework for drug–target interactions and adverse effects prediction

dc.contributor.advisorAlam, Md. Golam Rabiul
dc.contributor.authorMirza, Md. Sabbir Hossain
dc.contributor.authorChowdhury, Fahmid Hasan
dc.contributor.authorRafiq, Zakaria Ibne
dc.contributor.authorDhali, Radito
dc.contributor.authorTalukder, Md. Rakibul Hasan
dc.date.accessioned2026-04-20T06:04:44Z
dc.date.available2026-04-20T06:04:44Z
dc.date.issued2026-01
dc.descriptionCataloged from PDF version of thesis.
dc.descriptionIncludes bibliographical references (pages 80-83).
dc.descriptionThis thesis is submitted in partial fulfillment of the requirements for the degree of Bachelor of Science in Computer Science, 2026.
dc.description.abstractDrug-target interactions (DTIs) and adverse drug reactions (ADRs) are biological processes that interact closely but are difficult to model together, preventing the investigation of off-target effects and system perturbations that underlie drug safety. We introduce a single deep-learning system to predict both DTI and ADR using diverse molecular and protein representations of drug SMILES sequences and three-dimensional molecular graphs as well as protein sequences and structural features provided by AlphaFold. Curated DTI and drug-ADR data have a common RxNorm identifier that facilitates the cross-task correspondence between these two data.The proposed context-aware multi-task model uses variational auto-encoder bottleneck to both regularize shared latent space and multihead predictors for binary DTI classification and multi-label ADR with strong label imbalance. In contrast to the previous methods where interaction and safety modeling are decoupled or a single-modality evidence is used, in the model, drug-protein-ADR context is learned jointly. At the drug and protein concentrations, cold-start split analysis show decision-relevant predictions, which are calibrated, and good extrapolation to unfamiliar objects. In addition to predictive performance, the pipeline has a modular and reproducible prediction framework between featurization and inference enabling scalable experimentation. It continues the integration of DTI-ADR modeling as a conceptual method of early safety triage, risk-conscious virtual screening and translational drug discovery. Under stringent protein-level cold-start evaluation, the proposed framework achieves strong and stable performance, attaining a DTI AUROC of 91.60%, AUPRC of 85.46%, and F1-score of 78.39%, alongside ADR prediction with a weighted AUROC of 98.80% and weighted AUPRC of 94.54%, consistently reproduced across multiple random seeds.
dc.identifier.otherID 23241086
dc.identifier.otherID 21201286
dc.identifier.otherID 24341150
dc.identifier.otherID 24141150
dc.identifier.otherID 23241100
dc.identifier.otherhttps://dspace.bracu.ac.bd/server/api/core/items/7a5e2f21-4eb4-457c-b927-8366d04ee73e
dc.identifier.urihttp://hdl.handle.net/10361/27961
dc.language.isoen
dc.publisherBRAC University
dc.sourceBRAC University Institutional Repository
dc.subjectDrug–Target Interaction
dc.subjectAdverse drug reaction
dc.subjectMulti- task deep learning
dc.subjectGraph neural network
dc.subjectComputational drug discovery
dc.titleMulti-task learning framework for drug–target interactions and adverse effects prediction
dc.typeThesis

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