Saved in:
Bibliographic Details
Main Authors: Samadifardheris, Alireza, Poot, Dirk H. J., Wiesinger, Florian, Klein, Stefan, Hernandez-Tamames, Juan A.
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2512.17612
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866915686502105088
author Samadifardheris, Alireza
Poot, Dirk H. J.
Wiesinger, Florian
Klein, Stefan
Hernandez-Tamames, Juan A.
author_facet Samadifardheris, Alireza
Poot, Dirk H. J.
Wiesinger, Florian
Klein, Stefan
Hernandez-Tamames, Juan A.
contents High-resolution (HR) quantitative MRI (qMRI) relaxometry provides objective tissue characterization but remains clinically underutilized due to lengthy acquisition times. We propose a physics-informed, self-supervised framework for qMRI super-resolution that uses routinely acquired HR weighted MRI (wMRI) scans as guidance, thus, removing the necessity for HR qMRI ground truth during training. We formulate super-resolution as Bayesian maximum a posteriori inference, minimizing two discrepancies: (1) between HR images synthesized from super-resolved qMRI maps and acquired wMRI guides via forward signal models, and (2) between acquired LR qMRI and downsampled predictions. This physics-informed objective allows the models to learn from clinical wMRI without HR qMRI supervision. To validate the concept, we generate training data by synthesizing wMRI guides from HR qMRI using signal equations, then degrading qMRI resolution via k-space truncation. A deep neural network learns the super-resolution mapping. Ablation experiments demonstrate that T1-weighted images primarily enhance T1 maps, T2-weighted images improve T2 maps, and combined guidance optimally enhances all parameters simultaneously. Validation on independently acquired in-vivo data from a different qMRI sequence confirms cross-qMRI sequence generalizability. Models trained on synthetic data can produce super-resolved maps from a 1-minute acquisition with quality comparable to a 5-minute reference scan, leveraging the scanner-independent nature of relaxometry parameters. By decoupling training from HR qMRI requirement, our framework enables fast qMRI acquisitions enhanced via routine clinical images, offering a practical pathway for integrating quantitative relaxometry into clinical workflows with acceptable additional scan time.
format Preprint
id arxiv_https___arxiv_org_abs_2512_17612
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Self-Supervised Weighted Image Guided Quantitative MRI Super-Resolution
Samadifardheris, Alireza
Poot, Dirk H. J.
Wiesinger, Florian
Klein, Stefan
Hernandez-Tamames, Juan A.
Computer Vision and Pattern Recognition
High-resolution (HR) quantitative MRI (qMRI) relaxometry provides objective tissue characterization but remains clinically underutilized due to lengthy acquisition times. We propose a physics-informed, self-supervised framework for qMRI super-resolution that uses routinely acquired HR weighted MRI (wMRI) scans as guidance, thus, removing the necessity for HR qMRI ground truth during training. We formulate super-resolution as Bayesian maximum a posteriori inference, minimizing two discrepancies: (1) between HR images synthesized from super-resolved qMRI maps and acquired wMRI guides via forward signal models, and (2) between acquired LR qMRI and downsampled predictions. This physics-informed objective allows the models to learn from clinical wMRI without HR qMRI supervision. To validate the concept, we generate training data by synthesizing wMRI guides from HR qMRI using signal equations, then degrading qMRI resolution via k-space truncation. A deep neural network learns the super-resolution mapping. Ablation experiments demonstrate that T1-weighted images primarily enhance T1 maps, T2-weighted images improve T2 maps, and combined guidance optimally enhances all parameters simultaneously. Validation on independently acquired in-vivo data from a different qMRI sequence confirms cross-qMRI sequence generalizability. Models trained on synthetic data can produce super-resolved maps from a 1-minute acquisition with quality comparable to a 5-minute reference scan, leveraging the scanner-independent nature of relaxometry parameters. By decoupling training from HR qMRI requirement, our framework enables fast qMRI acquisitions enhanced via routine clinical images, offering a practical pathway for integrating quantitative relaxometry into clinical workflows with acceptable additional scan time.
title Self-Supervised Weighted Image Guided Quantitative MRI Super-Resolution
topic Computer Vision and Pattern Recognition
url https://arxiv.org/abs/2512.17612