English

MDM: Molecular Diffusion Model for 3D Molecule Generation

Machine Learning 2022-09-14 v1 Biomolecules

Abstract

Molecule generation, especially generating 3D molecular geometries from scratch (i.e., 3D \textit{de novo} generation), has become a fundamental task in drug designs. Existing diffusion-based 3D molecule generation methods could suffer from unsatisfactory performances, especially when generating large molecules. At the same time, the generated molecules lack enough diversity. This paper proposes a novel diffusion model to address those two challenges. First, interatomic relations are not in molecules' 3D point cloud representations. Thus, it is difficult for existing generative models to capture the potential interatomic forces and abundant local constraints. To tackle this challenge, we propose to augment the potential interatomic forces and further involve dual equivariant encoders to encode interatomic forces of different strengths. Second, existing diffusion-based models essentially shift elements in geometry along the gradient of data density. Such a process lacks enough exploration in the intermediate steps of the Langevin dynamics. To address this issue, we introduce a distributional controlling variable in each diffusion/reverse step to enforce thorough explorations and further improve generation diversity. Extensive experiments on multiple benchmarks demonstrate that the proposed model significantly outperforms existing methods for both unconditional and conditional generation tasks. We also conduct case studies to help understand the physicochemical properties of the generated molecules.

Keywords

Cite

@article{arxiv.2209.05710,
  title  = {MDM: Molecular Diffusion Model for 3D Molecule Generation},
  author = {Lei Huang and Hengtong Zhang and Tingyang Xu and Ka-Chun Wong},
  journal= {arXiv preprint arXiv:2209.05710},
  year   = {2022}
}

Comments

Submitted to AAAI'23

R2 v1 2026-06-28T01:10:51.713Z