Accelerating MRI with Longitudinally-informed Latent Posterior Sampling

TL;DR

This paper introduces a diffusion-model-based MRI reconstruction method that leverages prior scans during inference to accelerate imaging, without needing longitudinal training data, and demonstrates improved image quality and robustness.

Contribution

The authors propose a novel framework that incorporates prior scans into diffusion-based MRI reconstruction without requiring paired training data, enhancing acceleration and robustness.

Findings

Outperforms baseline methods in SSIM and PSNR metrics.

Effective in regions similar to prior scans, with up to 10% higher SSIM.

Robust to anatomical changes and misregistration.

Abstract

Purpose: To accelerate MRI acquisition by incorporating the previous scans of a subject during reconstruction. Although longitudinal imaging constitutes much of clinical MRI, leveraging previous scans is challenging due to the complex relationship between scan sessions, potentially involving substantial anatomical or pathological changes, and the lack of open-access datasets with both longitudinal pairs and raw k-space needed for training deep learning-based reconstruction models. Methods: We propose a diffusion-model-based reconstruction framework that eliminates the need for longitudinally paired training data. During training, we treat all scan timepoints as samples from the same distribution, therefore requiring only standalone images. At inference, our framework integrates a subject's prior scan in magnitude DICOM format, which is readily available in clinical workflows, to guide reconstruction of the follow-up. To support future development, we introduce an open-access clinical dataset containing multi-session pairs including prior DICOMs and follow-up k-space. Results: Our method consistently outperforms both longitudinal and non-longitudinal baseline reconstruction methods across various accelerated Cartesian acquisition strategies. In imaging regions highly similar to the prior scan, we observe up to 10\% higher SSIM and 2 dB higher PSNR, without degradation in dissimilar areas. Compared to longitudinal reconstruction baselines, our method demonstrates robustness to varying degrees of anatomical change and misregistration. Conclusion: We demonstrate that prior scans can be effectively integrated with state-of-the-art diffusion-based reconstruction methods to improve image quality and enable greater scan acceleration, without requiring an extensive longitudinally-paired training dataset.