Minkai Xu scite author profile

Predicting molecular conformations from molecular graphs is a fundamental problem in cheminformatics and drug discovery. Recently, significant progress has been achieved with machine learning approaches, especially with deep generative models. Inspired by the diffusion process in classical non-equilibrium thermodynamics where heated particles will diffuse from original states to a noise distribution, in this paper, we propose a novel generative model named GEODIFF for molecular conformation prediction. GEODIFF treats each atom as a particle and learns to directly reverse the diffusion process (i.e., transforming from a noise distribution to stable conformations) as a Markov chain. Modeling such a generation process is however very challenging as the likelihood of conformations should be rototranslational invariant. We theoretically show that Markov chains evolving with equivariant Markov kernels can induce an invariant distribution by design, and further propose building blocks for the Markov kernels to preserve the desirable equivariance property. The whole framework can be efficiently trained in an end-toend fashion by optimizing a weighted variational lower bound to the (conditional) likelihood. Experiments on multiple benchmarks show that GEODIFF is superior or comparable to existing state-of-the-art approaches, especially on large molecules. 1

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Learning Gradient Fields for Molecular Conformation Generation

Shi

Luo

et al. 2021

Preprint

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We study a fundamental problem in computational chemistry known as molecular conformation generation, trying to predict stable 3D structures from 2D molecular graphs. Existing machine learning approaches usually first predict distances between atoms and then generate a 3D structure satisfying the distances, where noise in predicted distances may induce extra errors during 3D coordinate generation. Inspired by the traditional force field methods for molecular dynamics simulation, in this paper, we propose a novel approach called ConfGF by directly estimating the gradient fields of the log density of atomic coordinates. The estimated gradient fields allow directly generating stable conformations via Langevin dynamics. However, the problem is very challenging as the gradient fields are rototranslation equivariant. We notice that estimating the gradient fields of atomic coordinates can be translated to estimating the gradient fields of interatomic distances, and hence develop a novel algorithm based on recent score-based generative models to effectively estimate these gradients. Experimental results across multiple tasks show that ConfGF outperforms previous state-of-the-art baselines by a significant margin.

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Learning Neural Generative Dynamics for Molecular Conformation Generation

Xu¹,

Luo²,

Bengio³

et al. 2021

Preprint

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We study how to generate molecule conformations (i.e., 3D structures) from a molecular graph. Traditional methods, such as molecular dynamics, sample conformations via computationally expensive simulations. Recently, machine learning methods have shown great potential by training on a large collection of conformation data. Challenges arise from the limited model capacity for capturing complex distributions of conformations and the difficulty in modeling long-range dependencies between atoms. Inspired by the recent progress in deep generative models, in this paper, we propose a novel probabilistic framework to generate valid and diverse conformations given a molecular graph. We propose a method combining the advantages of both flow-based and energy-based models, enjoying:(1) a high model capacity to estimate the multimodal conformation distribution;(2) explicitly capturing the complex long-range dependencies between atoms in the observation space. Extensive experiments demonstrate the superior performance of the proposed method on several benchmarks, including conformation generation and distance modeling tasks, with a significant improvement over existing generative models for molecular conformation sampling. * Equal contribution. Work was done during Shitong's internship at Mila.

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Generative Coarse-Graining of Molecular Conformations

Wang¹,

Xu²,

Miller³

et al. 2022

Preprint

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Axial coordination tuning Fe single-atom catalysts for boosting H2O2 activation

Wei

Chen

et al. 2023

Applied Catalysis B: Environmental

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Minkai Xu

GeoDiff: a Geometric Diffusion Model for Molecular Conformation Generation

Learning Gradient Fields for Molecular Conformation Generation

Learning Neural Generative Dynamics for Molecular Conformation Generation

Generative Coarse-Graining of Molecular Conformations

Axial coordination tuning Fe single-atom catalysts for boosting H2O2 activation

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