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Autori principali: Zhang, Runshi, Mo, Hao, Wang, Junchen, Jie, Bimeng, He, Yang, Jin, Nenghao, Zhu, Liang
Natura: Preprint
Pubblicazione: 2024
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Accesso online:https://arxiv.org/abs/2410.20348
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author Zhang, Runshi
Mo, Hao
Wang, Junchen
Jie, Bimeng
He, Yang
Jin, Nenghao
Zhu, Liang
author_facet Zhang, Runshi
Mo, Hao
Wang, Junchen
Jie, Bimeng
He, Yang
Jin, Nenghao
Zhu, Liang
contents Complicated image registration is a key issue in medical image analysis, and deep learning-based methods have achieved better results than traditional methods. The methods include ConvNet-based and Transformer-based methods. Although ConvNets can effectively utilize local information to reduce redundancy via small neighborhood convolution, the limited receptive field results in the inability to capture global dependencies. Transformers can establish long-distance dependencies via a self-attention mechanism; however, the intense calculation of the relationships among all tokens leads to high redundancy. We propose a novel unsupervised image registration method named the unified Transformer and superresolution (UTSRMorph) network, which can enhance feature representation learning in the encoder and generate detailed displacement fields in the decoder to overcome these problems. We first propose a fusion attention block to integrate the advantages of ConvNets and Transformers, which inserts a ConvNet-based channel attention module into a multihead self-attention module. The overlapping attention block, a novel cross-attention method, uses overlapping windows to obtain abundant correlations with match information of a pair of images. Then, the blocks are flexibly stacked into a new powerful encoder. The decoder generation process of a high-resolution deformation displacement field from low-resolution features is considered as a superresolution process. Specifically, the superresolution module was employed to replace interpolation upsampling, which can overcome feature degradation. UTSRMorph was compared to state-of-the-art registration methods in the 3D brain MR (OASIS, IXI) and MR-CT datasets. The qualitative and quantitative results indicate that UTSRMorph achieves relatively better performance. The code and datasets are publicly available at https://github.com/Runshi-Zhang/UTSRMorph.
format Preprint
id arxiv_https___arxiv_org_abs_2410_20348
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle UTSRMorph: A Unified Transformer and Superresolution Network for Unsupervised Medical Image Registration
Zhang, Runshi
Mo, Hao
Wang, Junchen
Jie, Bimeng
He, Yang
Jin, Nenghao
Zhu, Liang
Computer Vision and Pattern Recognition
Complicated image registration is a key issue in medical image analysis, and deep learning-based methods have achieved better results than traditional methods. The methods include ConvNet-based and Transformer-based methods. Although ConvNets can effectively utilize local information to reduce redundancy via small neighborhood convolution, the limited receptive field results in the inability to capture global dependencies. Transformers can establish long-distance dependencies via a self-attention mechanism; however, the intense calculation of the relationships among all tokens leads to high redundancy. We propose a novel unsupervised image registration method named the unified Transformer and superresolution (UTSRMorph) network, which can enhance feature representation learning in the encoder and generate detailed displacement fields in the decoder to overcome these problems. We first propose a fusion attention block to integrate the advantages of ConvNets and Transformers, which inserts a ConvNet-based channel attention module into a multihead self-attention module. The overlapping attention block, a novel cross-attention method, uses overlapping windows to obtain abundant correlations with match information of a pair of images. Then, the blocks are flexibly stacked into a new powerful encoder. The decoder generation process of a high-resolution deformation displacement field from low-resolution features is considered as a superresolution process. Specifically, the superresolution module was employed to replace interpolation upsampling, which can overcome feature degradation. UTSRMorph was compared to state-of-the-art registration methods in the 3D brain MR (OASIS, IXI) and MR-CT datasets. The qualitative and quantitative results indicate that UTSRMorph achieves relatively better performance. The code and datasets are publicly available at https://github.com/Runshi-Zhang/UTSRMorph.
title UTSRMorph: A Unified Transformer and Superresolution Network for Unsupervised Medical Image Registration
topic Computer Vision and Pattern Recognition
url https://arxiv.org/abs/2410.20348