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3D-GSRD: 3D Molecular Graph Auto-Encoder with Selective Re-mask Decoding

graph-neural-networks › molecular-modeling

📄 Abstract

Abstract: Masked graph modeling (MGM) is a promising approach for molecular representation learning (MRL).However, extending the success of re-mask decoding from 2D to 3D MGM is non-trivial, primarily due to two conflicting challenges: avoiding 2D structure leakage to the decoder, while still providing sufficient 2D context for reconstructing re-masked atoms. To address these challenges, we propose 3D-GSRD: a 3D Molecular Graph Auto-Encoder with Selective Re-mask Decoding. The core innovation of 3D-GSRD lies in its Selective Re-mask Decoding(SRD), which re-masks only 3D-relevant information from encoder representations while preserving the 2D graph structures. This SRD is synergistically integrated with a 3D Relational-Transformer(3D-ReTrans) encoder alongside a structure-independent decoder. We analyze that SRD, combined with the structure-independent decoder, enhances the encoder's role in MRL. Extensive experiments show that 3D-GSRD achieves strong downstream performance, setting a new state-of-the-art on 7 out of 8 targets in the widely used MD17 molecular property prediction benchmark. The code is released at https://github.com/WuChang0124/3D-GSRD.

Authors (9)

Chang Wu

Zhiyuan Liu

Wen Shu

Liang Wang

Yanchen Luo

Wenqiang Lei

+3 more

Submitted

October 19, 2025

arXiv Category

cs.LG

arXiv PDF

Key Contributions

Introduces 3D-GSRD, a 3D molecular graph auto-encoder with Selective Re-mask Decoding (SRD) to address challenges in 3D masked graph modeling. SRD selectively re-masks 3D-relevant information while preserving 2D graph structures, enhancing encoder role in molecular representation learning.

Business Value

Enables more accurate and efficient learning of molecular representations, potentially accelerating drug discovery and materials design by improving predictive models for molecular properties.

Paper Metadata

Innovation Type

Algorithmic

Deployment Feasibility

Moderate. Requires specialized graph processing capabilities and potentially large datasets for training.

Limitations Addressed

Difficulty in extending 2D re-mask decoding to 3D MGM without 2D structure leakage or insufficient 2D context for reconstruction.

Technical Tags

graph auto-encodermasked graph modeling3D molecular graphsselective re-mask decodingrelational transformerstructure-independent decodermolecular representation learning

Research Topics

Molecular Representation LearningGraph Neural NetworksDeep Generative Models3D Structure LearningSelf-Supervised Learning

Methods & Architectures

Graph Auto-EncoderMasked Graph ModelingSelective Re-mask Decoding (SRD)3D Relational-Transformer (3D-ReTrans)Structure-Independent Decoder Graph Auto-EncoderTransformer

Applications & Tasks

Drug Discovery Materials Science Computational Chemistry Representation LearningGenerative ModelingStructure Prediction Molecular Property PredictionMolecule GenerationDrug Design

Related Fields

Machine LearningComputational ChemistryCheminformaticsDeep Learning

Keywords

molecular graphautoencodermasked graph modeling3Drepresentation learningdeep learningtransformerdrug discoverycheminformaticsgraph neural networks

Academic Context

#Molecular Representation Learning#Graph Neural Networks#Deep Generative Models#3D Structure Learning#Self-Supervised Learning

Commercial Potential

Potential Products

Molecular property prediction softwareDrug candidate screening platforms

Target Industries

PharmaceuticalsBiotechnologyMaterials Science

Use Case Examples

Predicting drug toxicityDesigning novel molecules with desired properties

Competitive Edge

Offers a novel approach to 3D masked graph modeling that aims to overcome limitations of existing 2D-based methods.

Market Opportunity

Large and growing market for AI in drug discovery and materials science.

Revenue Models

Licensing of technologySaaS for prediction services.

Resource Requirements

Compute Needs

High (for training deep graph models)

Data Requirements

Large datasets of 3D molecular structures

Deployment Constraints

Computational resources for inference, integration with existing cheminformatics pipelines.

Scalability

Scalability depends on the efficiency of graph processing and transformer components.

Production Readiness

Maturity Level

Research

Time to Market

2-5 years

Patent Potential

Low to Moderate (algorithmic innovation)

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