arxiv_ai 95% Match Research Paper Computational chemists,Drug discovery scientists,Materials scientists,AI researchers in graph learning 1 week ago

M-GLC: Motif-Driven Global-Local Context Graphs for Few-shot Molecular Property Prediction

graph-neural-networks › molecular-modeling

📄 Abstract

Abstract: Molecular property prediction (MPP) is a cornerstone of drug discovery and materials science, yet conventional deep learning approaches depend on large labeled datasets that are often unavailable. Few-shot Molecular property prediction (FSMPP) addresses this scarcity by incorporating relational inductive bias through a context graph that links molecule nodes to property nodes, but such molecule-property graphs offer limited structural guidance. We propose a comprehensive solution: Motif Driven Global-Local Context Graph for few-shot molecular property prediction, which enriches contextual information at both the global and local levels. At the global level, chemically meaningful motif nodes representing shared substructures, such as rings or functional groups, are introduced to form a global tri-partite heterogeneous graph, yielding motif-molecule-property connections that capture long-range compositional patterns and enable knowledge transfer among molecules with common motifs. At the local level, we build a subgraph for each node in the molecule-property pair and encode them separately to concentrate the model's attention on the most informative neighboring molecules and motifs. Experiments on five standard FSMPP benchmarks demonstrate that our framework consistently outperforms state-of-the-art methods. These results underscore the effectiveness of integrating global motif knowledge with fine-grained local context to advance robust few-shot molecular property prediction.

Authors (2)

Xiangyang Xu

Hongyang Gao

Submitted

October 24, 2025

arXiv Category

cs.LG

arXiv PDF

Key Contributions

This paper proposes a Motif Driven Global-Local Context Graph (M-GLC) approach for few-shot molecular property prediction (FSMPP). It enriches context by introducing chemically meaningful motif nodes to form a global tri-partite heterogeneous graph, capturing long-range compositional patterns and enabling better knowledge transfer, thereby addressing limitations of existing context graph methods in FSMPP.

Business Value

Accelerates drug discovery and materials design by enabling accurate property predictions even with scarce experimental data, reducing R&D costs and time-to-market for new molecules.

Paper Metadata

Innovation Type

Methodological

Deployment Feasibility

Feasible within computational chemistry and drug discovery pipelines. Requires expertise in GNNs and molecular representation. Integration with existing cheminformatics tools is possible.

Limitations Addressed

Addresses the limitations of conventional deep learning approaches in molecular property prediction that require large labeled datasets, and the limited structural guidance offered by existing molecule-property graphs in few-shot settings.

Technical Tags

molecular property predictionfew-shot learninggraph neural networksmotif-driven graphsheterogeneous graphsdrug discoverymaterials scienceinductive biasknowledge transfer

Research Topics

Machine Learning for ChemistryGraph Neural NetworksDrug DiscoveryMaterials ScienceFew-Shot Learning

Methods & Architectures

Motif-Driven Global-Local Context GraphsHeterogeneous Graph ConstructionFew-Shot Learning techniques Graph Neural Networks (GNNs)

Applications & Tasks

Drug Discovery Materials Science Computational Chemistry Few-Shot LearningMolecular Property PredictionData Scarcity in Scientific Domains Predicting molecular properties with limited dataImproving generalization in molecular property predictionCapturing compositional patterns in molecules

Related Fields

CheminformaticsComputational ChemistryMachine LearningGraph Neural NetworksDrug DiscoveryMaterials Science

Keywords

molecular property predictionfew-shot learninggraph neural networksGNNheterogeneous graphmotifdrug discoverymaterials sciencecheminformaticsknowledge transfer

Academic Context

#Machine Learning for Chemistry#Graph Neural Networks#Drug Discovery#Materials Science#Few-Shot Learning

Commercial Potential

Potential Products

Accelerated drug candidate screening platformMaterials property prediction softwareCheminformatics analysis tools

Target Industries

PharmaceuticalsBiotechnologyChemicalsMaterials Science

Use Case Examples

Predicting the binding affinity of potential drug candidates with limited experimental dataDesigning novel materials with desired propertiesAccelerating the screening of chemical libraries

Competitive Edge

Offers a more effective approach to few-shot molecular property prediction by incorporating chemically meaningful motifs and richer graph structures, potentially outperforming methods relying solely on molecule-property graphs.

Market Opportunity

Large and growing market for AI-driven drug discovery and materials science solutions.

Revenue Models

Licensing of software/algorithmsproviding prediction servicescollaborative research projects.

Resource Requirements

Compute Needs

Moderate to high, depending on the size of the molecular graphs and the complexity of the GNN architecture. Requires GPUs for efficient training.

Data Requirements

Requires datasets of molecules with associated properties, suitable for few-shot learning scenarios (i.e., limited labeled examples per property).

Deployment Constraints

Performance depends on the quality of motif identification and graph construction. Requires careful validation against experimental data. Interpretability of GNN predictions can be a challenge.

Scalability

Scalable to large molecular datasets, but computational cost increases with graph size and complexity.

Regulatory Considerations

None directlybut applications in drug discovery are subject to stringent regulatory pathways (e.g.FDA).

Production Readiness

Maturity Level

Research/Development

Time to Market

2-4 years for integration into drug discovery pipelines.

Patent Potential

Moderate, potentially for novel graph construction methods or specific applications in drug/material design.

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