Domain-randomized deep learning for neuroimage analysis

TL;DR

This paper reviews a domain-randomization deep learning approach that enhances neuroimage analysis by improving model robustness and generalization across diverse imaging modalities and conditions.

Contribution

It provides a comprehensive overview of synthesis-driven training, highlighting its principles, benefits, and practical considerations for neuroimaging applications.

Findings

Effective across multiple imaging modalities including MRI and CT

Improves model generalization without retraining or fine-tuning

Increases resistance to overfitting and enhances robustness

Abstract

Deep learning has revolutionized neuroimage analysis by delivering unprecedented speed and accuracy. However, the narrow scope of many training datasets constrains model robustness and generalizability. This challenge is particularly acute in magnetic resonance imaging (MRI), where image appearance varies widely across pulse sequences and scanner hardware. A recent domain-randomization strategy addresses the generalization problem by training deep neural networks on synthetic images with randomized intensities and anatomical content. By generating diverse data from anatomical segmentation maps, the approach enables models to accurately process image types unseen during training, without retraining or fine-tuning. It has demonstrated effectiveness across modalities including MRI, computed tomography, positron emission tomography, and optical coherence tomography, as well as beyond neuroimaging in ultrasound, electron and fluorescence microscopy, and X-ray microtomography. This tutorial paper reviews the principles, implementation, and potential of the synthesis-driven training paradigm. It highlights key benefits, such as improved generalization and resistance to overfitting, while discussing trade-offs such as increased computational demands. Finally, the article explores practical considerations for adopting the technique, aiming to accelerate the development of generalizable tools that make deep learning more accessible to domain experts without extensive computational resources or machine learning knowledge.