MIRNF: Medical Image Registration via Neural Fields
- URL: http://arxiv.org/abs/2206.03111v1
- Date: Tue, 7 Jun 2022 08:43:31 GMT
- Title: MIRNF: Medical Image Registration via Neural Fields
- Authors: Shanlin Sun and Kun Han and Deying Kong and Chenyu You and Xiaohui Xie
- Abstract summary: We introduce a new deep-neural net-based image registration framework, named textbfMIRNF.
MIRNF represents the correspondence mapping with a continuous function implemented via Neural Fields.
We conduct experiments on two 3D MR brain scan datasets, showing that our proposed framework provides state-of-art registration performance.
- Score: 19.302770031855097
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Image registration is widely used in medical image analysis to provide
spatial correspondences between two images. Recently learning-based methods
utilizing convolutional neural networks (CNNs) have been proposed for solving
image registration problems. The learning-based methods tend to be much faster
than traditional optimization-based methods, but the accuracy improvements
gained from the complex CNN-based methods are modest. Here we introduce a new
deep-neural net-based image registration framework, named \textbf{MIRNF}, which
represents the correspondence mapping with a continuous function implemented
via Neural Fields. MIRNF outputs either a deformation vector or velocity vector
given a 3D coordinate as input. To ensure the mapping is diffeomorphic, the
velocity vector output from MIRNF is integrated using the Neural ODE solver to
derive the correspondences between two images. Furthermore, we propose a hybrid
coordinate sampler along with a cascaded architecture to achieve the
high-similarity mapping performance and low-distortion deformation fields. We
conduct experiments on two 3D MR brain scan datasets, showing that our proposed
framework provides state-of-art registration performance while maintaining
comparable optimization time.
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