Abstract
MR super-resolution is reformulated as a physics-aware reconstruction problem that dynamically adapts resolution-SNR configurations using Gaussian splatting with prior-aware representations and physics-constrained modeling.
Magnetic resonance imaging (MRI) super-resolution is vital for improving diagnostic accessibility, yet most methods treat it as a deterministic mapping from a fixed low-resolution input to a high-resolution target. This overlooks a key property of MRI acquisition physics: spatial resolution and signal-to-noise ratio (SNR) are inherently coupled, making any given low-resolution scan merely one of many possible realizations under varying acquisition trade-offs. We rethink MRI super-resolution as a physics-aware reconstruction problem, in which the goal is to identify the optimal resolution-SNR configuration and then super-resolve it to obtain high-quality MRI results. A key implication of this formulation is that MRI resolution becomes dynamic rather than fixed. To handle such resolution-heterogeneous inputs, we adapt 2D Gaussian Splatting (2D GS) to MRI by formulating reconstruction as a coordinate-based, resolution-agnostic rendering problem. To further enhance fidelity, we introduce three innovations: (1) a prior-aware Gaussian representation that combines an Anatomical Structure Prior for tissue-specific kernel initialization with an Imaging System Prior that captures hardware characteristics via a covariance dictionary; (2) a physics-constrained signal modeling scheme that predicts intrinsic tissue parameters (proton density rho and effective relaxation rate R2) and synthesizes intensities through governing physical equations, ensuring biophysically plausible contrast; and (3) a meta-learning framework that alleviates paired-data scarcity by pretraining on simulated data and adapting to real-world conditions. Extensive experiments on dynamic-resolution datasets and standard benchmarks demonstrate that our method achieves state-of-the-art performance, highlighting its strong potential for clinical deployment.
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This paper reframes MRI super-resolution as a physics-aware problem, recognizing that resolution and SNR are inherently coupled in MRI acquisition, making resolution dynamic rather than fixed. The authors adapt 2D Gaussian Splatting as a resolution-agnostic representation and introduce physics-constrained signal modeling that predicts intrinsic tissue parameters (proton density and relaxation rate) to synthesize biophysically plausible images. A meta-learning framework addresses paired-data scarcity by pretraining on simulated data and adapting to real-world conditions, achieving state-of-the-art performance on both dynamic-resolution and standard benchmarks.
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