arxiv_ai 98% Match Research Paper AI Researchers,Computational Chemists,Drug Discovery Scientists,Materials Scientists 2 days ago

Graph Diffusion that can Insert and Delete

generative-ai › diffusion

📄 Abstract

Abstract: Generative models of graphs based on discrete Denoising Diffusion Probabilistic Models (DDPMs) offer a principled approach to molecular generation by systematically removing structural noise through iterative atom and bond adjustments. However, existing formulations are fundamentally limited by their inability to adapt the graph size (that is, the number of atoms) during the diffusion process, severely restricting their effectiveness in conditional generation scenarios such as property-driven molecular design, where the targeted property often correlates with the molecular size. In this paper, we reformulate the noising and denoising processes to support monotonic insertion and deletion of nodes. The resulting model, which we call GrIDDD, dynamically grows or shrinks the chemical graph during generation. GrIDDD matches or exceeds the performance of existing graph diffusion models on molecular property targeting despite being trained on a more difficult problem. Furthermore, when applied to molecular optimization, GrIDDD exhibits competitive performance compared to specialized optimization models. This work paves the way for size-adaptive molecular generation with graph diffusion.

Authors (3)

Matteo Ninniri

Marco Podda

Davide Bacciu

Submitted

June 6, 2025

arXiv Category

cs.LG

arXiv PDF

Key Contributions

Introduces GrIDDD, a novel graph diffusion model that overcomes the limitation of fixed graph size by enabling monotonic node insertion and deletion during generation. This allows for dynamic adaptation of molecular size, crucial for property-driven molecular design.

Business Value

Accelerates the discovery of novel molecules with desired properties for pharmaceuticals, materials science, and chemical industries, potentially reducing R&D costs and time.

Paper Metadata

Innovation Type

Algorithmic

Deployment Feasibility

Moderate. Requires significant computational resources for training and inference, but the core methodology is sound.

Limitations Addressed

Existing graph diffusion models are limited to fixed graph sizes, hindering their effectiveness in conditional generation scenarios where molecular size is a key property.

Performance Gains

Matches or exceeds performance of existing graph diffusion models on molecular property targeting.

Technical Tags

Graph GenerationDiffusion ModelsDenoising Diffusion Probabilistic Models (DDPM)Molecular DesignConditional GenerationNode InsertionNode DeletionGraph Size AdaptationChemical GraphsProperty-Driven Generation

Research Topics

Generative ModelsGraph Neural NetworksMolecular ModelingAI for Drug Discovery

Methods & Architectures

Reformulated noising/denoising processesMonotonic node insertionMonotonic node deletionGrIDDD model Diffusion ModelsGraph Diffusion Models

Applications & Tasks

Chemistry Drug Discovery Materials Science Graph GenerationConditional GenerationMolecular Property Optimization Generating molecules with specific propertiesDynamically growing/shrinking chemical graphsMolecular design

Datasets & Benchmarks

Benchmarks

Molecular property targeting (performance matching or exceeding existing models)

Molecular property prediction accuracyGraph generation quality

Related Fields

Machine LearningGraph TheoryComputational ChemistryGenerative Models

Keywords

Graph GenerationDiffusion ModelsDDPMMolecular DesignConditional GenerationNode InsertionNode DeletionGraph SizeChemistryDrug DiscoveryGenerative AIGrIDDD

Academic Context

#Generative Models#Graph Neural Networks#Molecular Modeling#AI for Drug Discovery

Commercial Potential

Potential Products

Drug candidate generation platformsMaterials design software

Target Industries

PharmaceuticalsBiotechnologyChemicalsMaterials Science

Use Case Examples

Designing novel drug molecules with specific binding affinities.Generating new materials with tailored electronic or mechanical properties.

Competitive Edge

Offers a significant advancement over existing graph diffusion models by enabling dynamic graph size adaptation, a capability previously lacking.

Market Opportunity

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

Revenue Models

Licensing of the technologySaaS platforms for molecular design.

Resource Requirements

Compute Needs

High, typical for training large generative models.

Data Requirements

Large datasets of molecular structures and their properties.

Deployment Constraints

Computational cost for training and inference.

Scalability

Scalable to larger molecular graphs and more complex property conditioning.

Regulatory Considerations

Potential implications for intellectual property of generated molecules.

Production Readiness

Maturity Level

Research

Time to Market

1-3 years for integration into specialized platforms.

Patent Potential

Moderate, potential for novel algorithms in molecular generation.

View Full Paper Back to Papers