arxiv_cv 95% Match Research Paper Medical Imaging Researchers,Radiologists,Neuroscientists,AI Researchers,Clinical Researchers 1 week ago

Towards Generalisable Foundation Models for 3D Brain MRI

computer-vision › medical-imaging

📄 Abstract

Abstract: Foundation models in artificial intelligence (AI) are transforming medical imaging by enabling general-purpose feature learning from large-scale, unlabeled datasets. In this work, we introduce BrainFound, a self-supervised foundation model for brain MRI, built by extending DINO-v2, a vision transformer originally designed for 2D natural images. BrainFound adapts DINO-v2 to model full 3D brain anatomy by incorporating volumetric information from sequential MRI slices, moving beyond conventional single-slice paradigms. It supports both single- and multimodal inputs, enabling a broad range of downstream tasks, including disease detection and image segmentation, while generalising across varied imaging protocols and clinical scenarios. We show that BrainFound consistently outperforms existing self-supervised pretraining strategies and supervised baselines, particularly in label-scarce and multi-contrast settings. By integrating information from diverse 3D MRI modalities (e.g., T1, T2, FLAIR), it enhances diagnostic accuracy and reduces dependency on extensive expert annotations. This flexibility makes BrainFound a scalable and practical solution for 3D neuroimaging pipelines, with significant potential for clinical deployment and research innovation.

Authors (3)

Moona Mazher

Geoff J. M. Parker

Daniel C. Alexander

Submitted

October 27, 2025

arXiv Category

cs.CV

arXiv PDF

Key Contributions

BrainFound is a self-supervised foundation model for 3D brain MRI, adapting the DINO-v2 vision transformer to process volumetric data. It enables general-purpose feature learning from large-scale unlabeled MRI, demonstrating superior performance in label-scarce and multi-contrast settings for tasks like disease detection and segmentation, generalizing across diverse imaging protocols.

Business Value

Accelerates AI development for brain MRI analysis, enabling more accurate and efficient diagnostics, personalized treatment planning, and deeper understanding of neurological diseases.

Paper Metadata

Innovation Type

Algorithmic

Deployment Feasibility

Moderate, requires significant computational resources for training and deployment, and integration into clinical workflows needs careful validation.

Limitations Addressed

Limited generalizability of AI models in medical imaging,Scarcity of labeled medical data,Challenges in analyzing multi-contrast and 3D MRI data,Adapting natural image models to medical images

Performance Gains

Consistently outperforms existing self-supervised pretraining strategies and supervised baselines

Technical Tags

foundation models3D brain MRIself-supervised learningDINO-v2vision transformervolumetric informationdisease detectionimage segmentationmulti-contrastlabel-scarce

Research Topics

Medical ImagingArtificial IntelligenceFoundation ModelsDeep LearningNeuroscience

Methods & Architectures

Self-supervised learningVision Transformer (ViT) adaptationVolumetric modelingTransfer learning DINO-v2 (adapted)Vision Transformer (ViT)3D Convolutional Networks (implied)

Applications & Tasks

Medical Diagnostics Neuroscience Research Radiology Clinical Trials Generalizability of AI modelsLabel scarcityMulti-contrast MRI analysisAdapting 2D models to 3D data Disease detectionImage segmentationFeature learning for brain MRI

Datasets & Benchmarks

Datasets

3D Brain MRI, T1 (implied)

Performance on downstream tasks (disease detection, segmentation)Generalization across imaging protocols and clinical scenarios

Related Fields

Medical ImagingArtificial IntelligenceDeep LearningNeuroscienceComputer Vision

Keywords

foundation modelsbrain MRI3D visionself-supervised learningDINO-v2vision transformermedical imagingdisease detectionsegmentationgeneralizabilitylabel-scarcemulti-contrastneuroscience

Academic Context

#Medical Imaging#Artificial Intelligence#Foundation Models#Deep Learning#Neuroscience

Technology Stack

Frameworks & Libraries

DINO-v2

Commercial Potential

Potential Products

AI-powered diagnostic tools for neurological disordersAutomated segmentation software for brain structuresPlatforms for large-scale neuroimaging research

Target Industries

HealthcarePharmaceuticalsBiotechnologyMedical Research

Use Case Examples

Early detection of Alzheimer's disease from MRI scansAutomated segmentation of tumors or lesions in brain scansIdentifying subtle biomarkers for neurological conditions

Competitive Edge

Represents a significant advancement in foundation models for 3D medical imaging, offering better generalizability and performance, especially in data-limited scenarios, compared to existing methods.

Market Opportunity

Massive market for medical imaging AI and diagnostics.

Revenue Models

Licensing to medical device manufacturersSaaS for hospitals and research institutionspartnerships with pharmaceutical companies.

Resource Requirements

Compute Needs

Very High, requires substantial GPU resources for training foundation models.

Data Requirements

Requires large-scale, diverse 3D brain MRI datasets, ideally with multiple contrasts and across different scanners/protocols.

Deployment Constraints

High computational cost for inference,Need for rigorous clinical validation and regulatory approval,Integration into existing PACS and clinical workflows

Scalability

Foundation models are designed for scalability, learning general features applicable to many downstream tasks.

Regulatory Considerations

Subject to strict regulations for medical devices (e.g., FDA, CE marking).

Production Readiness

Maturity Level

Research

Time to Market

3-5 years for clinical deployment due to validation and regulatory hurdles.

Patent Potential

Moderate, novel architectural adaptations or training strategies for foundation models in medical imaging could be patentable.

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