A Collaborative Model-driven Network for MRI Reconstruction

Deep learning (DL)-based methods offer a promising solution to reduce the prolonged scanning time in magnetic resonance imaging (MRI). While model-driven DL methods have demonstrated convincing results by incorporating prior knowledge into deep networks, further exploration is needed to optimize the integration of diverse priors.. Existing model-driven networks typically utilize linearly stacked unrolled cascades to mimic iterative solution steps in optimization algorithms. However, this approach needs to find a balance between different prior-based regularizers during training, resulting in slower convergence and suboptimal reconstructions. To overcome the limitations, we propose a collaborative model-driven network to maximally exploit the complementarity of different regularizers. We design attention modules to learn both the relative confidence (RC) and overall confidence (OC) for the intermediate reconstructions (IRs) generated by different prior-based subnetworks. RC assigns more weight to the areas of expertise of the subnetworks, enabling precise element-wise collaboration. We design correction modules to tackle bottleneck scenarios where both subnetworks exhibit low accuracy, and they further optimize the IRs based on OC maps. IRs across various stages are concatenated and fed to the attention modules to build robust and accurate confidence maps. Experimental results on multiple datasets showed significant improvements in the final results without additional computational costs. Moreover, the proposed model-driven network design strategy can be conveniently applied to various model-driven methods to improve their performance.