Joint affine and deformable three‐dimensional networks for brain MRI registration

Purpose Volumetric medical image registration has important clinical significance. Traditional registration methods may be time‐consuming when processing large volumetric data due to their iterative optimizations. In contrast, existing deep learning‐based networks can obtain the registration quickly...

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Bibliographic Details
Published in:Medical physics (Lancaster) 2021-03, Vol.48 (3), p.1182-1196
Main Authors: Zhu, Zhenyu, Cao, Yiqin, Qin, Chenchen, Rao, Yi, Lin, Di, Dou, Qi, Ni, Dong, Wang, Yi
Format: Article
Language:English
Subjects:
affine alignment
Algorithms
Brain - diagnostic imaging
brain MRI
convolutional neural networks
deformable image registration
end‐to‐end registration
Image Processing, Computer-Assisted
Imaging, Three-Dimensional
Magnetic Resonance Imaging
Neuroimaging
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Summary:Purpose Volumetric medical image registration has important clinical significance. Traditional registration methods may be time‐consuming when processing large volumetric data due to their iterative optimizations. In contrast, existing deep learning‐based networks can obtain the registration quickly. However, most of them require independent rigid alignment before deformable registration; these two steps are often performed separately and cannot be end‐to‐end. Methods We propose an end‐to‐end joint affine and deformable network for three‐dimensional (3D) medical image registration. The proposed network combines two deformation methods; the first one is for obtaining affine alignment and the second one is a deformable subnetwork for achieving the nonrigid registration. The parameters of the two subnetworks are shared. The global and local similarity measures are used as loss functions for the two subnetworks, respectively. Moreover, an anatomical similarity loss is devised to weakly supervise the training of the whole registration network. Finally, the trained network can perform deformable registration in one forward pass. Results The efficacy of our network was extensively evaluated on three public brain MRI datasets including Mindboggle101, LPBA40, and IXI. Experimental results demonstrate our network consistently outperformed several state‐of‐the‐art methods with respect to the metrics of Dice index (DSC), Hausdorff distance (HD), and average symmetric surface distance (ASSD). Conclusions The proposed network provides accurate and robust volumetric registration without any pre‐alignment requirement, which facilitates the end‐to‐end deformable registration.
ISSN:0094-2405
2473-4209
DOI:10.1002/mp.14674