GCL-RCA-Net: an RCA-RemUNet-enhanced graph-contrastive framework for hybrid data-driven and dual-branch physics-guided parallel MRI reconstruction.
Authors
Affiliations (2)
Affiliations (2)
- Department of Biomedical Engineering, Bangladesh University of Engineering and Technology, DSP Lab, ECE building, BUET, Dhaka, 1000, Bangladesh.
- Department of Electrical and Electronic Engineering, Bangladesh University of Engineering and Technology, Dhaka 1205, Dhaka, 1205, Bangladesh.
Abstract
Parallel magnetic resonance imaging (pMRI) with Cartesian equispaced undersampling accelerates acquisition but introduces structured aliasing that degrades reconstruction quality, especially at high acceleration factors. Although recent self-supervised and contrastive reconstruction methods have shown promise, most operate slice-wise and do not capture cross-slice anatomical continuity or align learned representations with physics-guided reconstruction. To address these limitations, we propose GCL-RCA-Net, an RCA-RemUNet-enhanced graph-contrastive framework for pMRI reconstruction under Cartesian equispaced undersampling. The method combines measurement-consistent data-driven initialization, a physics-guided dual-branch module, anatomy-aware graph contrastive priors, and multi-stage cross-domain refinement. The initial stage stabilizes reconstruction by directly restoring acquired k-space samples and learning missing data. A dual-branch module then exploits complementary physics through calibration-based generalized autocalibrating partially parallel acquisitions (GRAPPA) interpolation in k-space and sensitivity-encoding (SENSE)-based conjugate gradient refinement in the image domain, followed by adaptive branch selection and fusion. To model anatomical context, a self-supervised graph contrastive module encodes cross-slice continuity and non-local structural relationships, providing descriptors that guide the cascaded refinement network. Finally, a multi-stage lattice-style cross-domain fusion module jointly refines the data-driven estimate and fused physics output through coupled image- and k-space pathways, followed by final data consistency enforcement. On fastMRI brain data with acceleration factors from 2× to 8×, and in cross-anatomy evaluation on fastMRI knee data, GCL-RCA-Net consistently outperforms recent baselines under equispaced Cartesian undersampling. Relative to the strongest competing method, it achieves PSNR gains of 2.66-4.35 dB on brain and 0.31-3.03 dB on knee reconstruction, with corresponding improvements in structural similarity. The proposed framework shows that combining measurement-consistent data-driven estimation, physics-guided dual-branch refinement, and anatomy-aware graph contrastive priors yields robust and generalizable pMRI reconstruction under severe undersampling, with strong potential for faster, higher-quality, and clinically reliable MRI.