MR image reconstruction using densely connected residual convolutional networks

MR image reconstruction techniques based on deep learning have shown their capacity for reducing MRI acquisition time and performance improvement compared to analytical methods. Despite the many challenges in training these rather large networks, novel methodologies have enhanced the capability for having clinical-grade MR image reconstruction in real-time. In recent literature, novel developments have facilitated the utilization of deep networks in various image processing inverse problems. In particular, it has been reported multiple times that the performance of deep networks can be improved by using short connections between layers. In this study, we introduce a novel MRI reconstruction method that utilizes such short connections. The dense connections are used inside densely connected residual blocks. Inside these blocks, the feature maps are concatenated to the subsequent layers. In this way, the extracted information is propagated until the last stage of the block. We have evaluated this densely connected residual block's efficiency in MRI reconstruction settings, by augmenting different types of effective deep network models with these blocks in novel structures. The quantitative and qualitative results indicate that this original introduction of the densely connected blocks to the MR image reconstruction problem improves the reconstruction performance significantly.

Automated summary

MRI image reconstruction techniques based on deep learning have shown great potential in reducing MRI acquisition time and improving performance compared to analytical methods. Despite challenges in training large networks, novel methodologies have enhanced the capability for real-time clinical-grade MR image reconstruction. The efficiency of deep networks can be improved by using short connections between layers, with studies showing significant improvements in reconstruction performance by introducing densely connected residual blocks in MRI reconstruction settings.