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

Zhu, Zhenyu; Cao, Yiqin; Qin, Chenchen; Rao, Yi; Lin, Di; Dou, Qi; Ni, Dong; Wang, Yi

doi:10.1002/mp.14674

Cited by 15 publications

(26 citation statements)

References 33 publications

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“…We compared our method with four cutting‐edge registration networks, including VoxelMorph (VM), 15 FAIM, 22 Multi‐FC, 23 and JADN 24 . Among these compared methods, VM, FAIM, and Multi‐FC are unsupervised methods using only intensity‐based similarity to train their registration networks.…”

Section: Experiments and Resultsmentioning

confidence: 99%

“…The deformable subnetwork has an encoder‐decoder architecture, and includes a dilated convolutional block at the last layer of the encoder. The loss function for the registration backbone is defined as

{\pounds}_{reg}

\begin{equation} \begin{split} {\pounds}_{reg}(F, M) = & - {\pounds}_{affine}(F, M\circ \phi _{affine})\\ &- {\pounds}_{deformable}(F, M \circ \phi _{affine}\circ \phi _{deformable})\\ & + \lambda {\pounds}_{smooth}(\phi _{deformable}), \end{split} \end{equation}

where

{\pounds}_{affine}

and

{\pounds}_{deformable}

define similarity criterion (here, we use normalized cross‐correlation function 3 ), and

{\pounds}_{smooth}

regularizes the smoothness of the deformable displacement field

\phi _{deformable}

(here, we use a diffusion regularizer 24 ); operator ○ is a warping operation; λ is a weighting parameter.…”

Section: Methodsmentioning

confidence: 99%

“…The general idea is to assist the registration process by introducing anatomical information, for example, the extracted corresponding anatomical landmarks or structures. Zhu et al 24 developed a weakly supervised registration network via an additional shape similarity loss to improve registration performance over unsupervised training. Hu et al 25 proposed a weakly supervised, label‐driven formulation to learn 3D voxel correspondence from higher‐level label correspondence, thereby bypassing classical intensity‐based image similarity measures.…”

Section: Introductionmentioning

confidence: 99%

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Salient deformable network for abdominal multiorgan registration

2022

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Background: Image registration has long been an active research area in the society of medical image computing, which is to perform spatial transformation between a pair of images and establish a point-wise correspondence to achieve spatial consistency. Purpose: Previous work mainly focused on learning complicated deformation fields by maximizing the global-level (i.e., foreground plus background) image similarity.We argue that taking the background similarity into account may not be a good solution, if we only seek the accurate alignment of target organs/regions in real clinical practice. Methods: We, therefore, propose a novel concept of Salient Registration and introduce a novel deformable network equipped with a saliency module. Specifically, a multitask learning-based saliency module is proposed to discriminate the salient regions-of -registration in a semisupervised manner. Then, our deformable network analyzes the intensity and anatomical similarity of salient regions, and finally conducts the salient deformable registration. Results: We evaluate the efficacy of the proposed network on challenging abdominal multiorgan CT scans. The experimental results demonstrate that the proposed registration network outperforms other state-of -the-art methods, achieving a mean Dice similarity coefficient (DSC) of 40.2%,Hausdorff distance (95 HD) of 20.8 mm, and average symmetric surface distance (ASSD) of 4.58 mm. Moreover, even by training using one labeled data, our network can still attain satisfactory registration performance, with a mean DSC of 39.2%, 95 HD of 21.2 mm, and ASSD of 4.78 mm. Conclusions:The proposed network provides an accurate solution for multiorgan registration and has the potential to be used for improving other registration applications. The code is publicly available at https://github.com/Rrrfrr/Salient-Deformable-Network.

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Section: Experiments and Resultsmentioning

confidence: 99%

{\pounds}_{reg}

\begin{equation} \begin{split} {\pounds}_{reg}(F, M) = & - {\pounds}_{affine}(F, M\circ \phi _{affine})\\ &- {\pounds}_{deformable}(F, M \circ \phi _{affine}\circ \phi _{deformable})\\ & + \lambda {\pounds}_{smooth}(\phi _{deformable}), \end{split} \end{equation}

where

{\pounds}_{affine}

and

{\pounds}_{deformable}

define similarity criterion (here, we use normalized cross‐correlation function 3 ), and

{\pounds}_{smooth}

regularizes the smoothness of the deformable displacement field

\phi _{deformable}

(here, we use a diffusion regularizer 24 ); operator ○ is a warping operation; λ is a weighting parameter.…”

Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Salient deformable network for abdominal multiorgan registration

2022

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“…All the above-described networks achieved promising registration accuracy across various datasets. Moreover, aside from purely deformable registration, Zhu et al used a registration scheme that combined both affine and deformable MR-MR brain registration methods (101). The affine network used global similarity as the loss function, whereas the deformable network used local similarity.…”

Section: Applicationsmentioning

confidence: 99%

A review of deep learning-based three-dimensional medical image registration methods

Xiao¹,

Teng²,

Liu³

et al. 2021

Quant Imaging Med Surg

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Medical image registration is a vital component of many medical procedures, such as imageguided radiotherapy (IGRT), as it allows for more accurate dose-delivery and better management of side effects. Recently, the successful implementation of deep learning (DL) in various fields has prompted many research groups to apply DL to three-dimensional (3D) medical image registration. Several of these efforts have led to promising results. This review summarized the progress made in DL-based 3D image registration over the past 5 years and identify existing challenges and potential avenues for further research.The collected studies were statistically analyzed based on the region of interest (ROI), image modality, supervision method, and registration evaluation metrics. The studies were classified into three categories: deep iterative registration, supervised registration, and unsupervised registration. The studies are thoroughly reviewed and their unique contributions are highlighted. A summary is presented following a review of each category of study, discussing its advantages, challenges, and trends. Finally, the common challenges for all categories are discussed, and potential future research topics are identified.

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“…Deep neural networks have achieved outstanding achievements in many areas of medical image computing, 1 including de‐noising, 9,10 super‐resolution, 11,12 cancer detection, 13 registration, 14 and single organ segmentation (e.g., heart, 15 prostate, 16 liver 17 ). However, multi‐organ segmentation is still a challenging task (e.g., abdominal multi‐organs 18 ).…”

Section: Introductionmentioning

confidence: 99%

Variance‐aware attention U‐Net for multi‐organ segmentation

Lin

Yang

et al. 2021

Medical Physics

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With the continuous development of deep learning based medical image segmentation technology, it is expected to attain more robust and accurate performance for more challenging tasks, such as multi-organs, small/irregular areas, and ambiguous boundary issues. Methods: We propose a variance-aware attention U-Net to solve the problem of multi-organ segmentation. Specifically, a simple yet effective variancebased uncertainty mechanism is devised to evaluate the discrimination of each voxel via its prediction probability. The proposed variance uncertainty is further embedded into an attention architecture, which not only aggregates multi-level deep features in a global-level but also enforces the network to pay extra attention to voxels with uncertain predictions during training. Results: Extensive experiments on challenging abdominal multi-organ CT dataset show that our proposed method consistently outperforms cutting-edge attention networks with respect to the evaluation metrics of Dice index (DSC), 95% Hausdorff distance (95HD) and average symmetric surface distance (ASSD). Conclusions:The proposed network provides an accurate and robust solution for multi-organ segmentation and has the potential to be used for improving other segmentation applications.

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

Cited by 15 publications

References 33 publications

Salient deformable network for abdominal multiorgan registration

Salient deformable network for abdominal multiorgan registration

A review of deep learning-based three-dimensional medical image registration methods

Variance‐aware attention U‐Net for multi‐organ segmentation

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