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MODA: A Unified 3D Diffusion Framework for Multi-Task Target-Aware Molecular Generation

Biomolecules 2025-07-11 v1 Artificial Intelligence Machine Learning

Abstract

Three-dimensional molecular generators based on diffusion models can now reach near-crystallographic accuracy, yet they remain fragmented across tasks. SMILES-only inputs, two-stage pretrain-finetune pipelines, and one-task-one-model practices hinder stereochemical fidelity, task alignment, and zero-shot transfer. We introduce MODA, a diffusion framework that unifies fragment growing, linker design, scaffold hopping, and side-chain decoration with a Bayesian mask scheduler. During training, a contiguous spatial fragment is masked and then denoised in one pass, enabling the model to learn shared geometric and chemical priors across tasks. Multi-task training yields a universal backbone that surpasses six diffusion baselines and three training paradigms on substructure, chemical property, interaction, and geometry. Model-C reduces ligand-protein clashes and substructure divergences while maintaining Lipinski compliance, whereas Model-B preserves similarity but trails in novelty and binding affinity. Zero-shot de novo design and lead-optimisation tests confirm stable negative Vina scores and high improvement rates without force-field refinement. These results demonstrate that a single-stage multi-task diffusion routine can replace two-stage workflows for structure-based molecular design.

Keywords

Cite

@article{arxiv.2507.07201,
  title  = {MODA: A Unified 3D Diffusion Framework for Multi-Task Target-Aware Molecular Generation},
  author = {Dong Xu and Zhangfan Yang and Sisi Yuan and Jenna Xinyi Yao and Jiangqiang Li and Junkai Ji},
  journal= {arXiv preprint arXiv:2507.07201},
  year   = {2025}
}
R2 v1 2026-07-01T03:53:49.226Z