MDReg‐Net: Multi‐resolution diffeomorphic image registration using fully convolutional networks with deep self‐supervision

Li, Hongming; Fan, Yong

doi:10.1002/hbm.25782

Cited by 26 publications

(17 citation statements)

References 50 publications

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“…We don't need this information, which is another clear distinction between our approach and earlier research. The previous two works (Li & Fan, 2017;Vos, Berendsen, Viergever, Staring, & Išgum, 2017) reported unsupervised methods that are close to ours. Both use the CNN neural network with spatial transformation function (Jaderberg et al, 2015), which warps images on top of each other and has significant problems: they only operate on a limited subset of volumes and only support small transformations.…”

Section: Discussionsupporting

confidence: 85%

DeepRetroMoCo: Deep neural network-based Retrospective Motion Correction Algorithm for Spinal Cord functional MRI

Mobarak-Abadi¹,

Mahmoudi-Aznave²,

Dehghani

et al. 2022

Preprint

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There are unique challenges in the preprocessing of spinal cord fMRI data, particularly voluntary or involuntary movement artifacts during image acquisition. Despite advances in data processing techniques for movement detection and correction, there are challenges in extrapolating motion correction algorithm developments in the brain cortex to the brainstem and spinal cord. We trained a Deep Learning-based convolutional neural network (CNN) via an unsupervised learning algorithm, called DeepRetroMoCo, to detect and correct motions in axial T2*-weighted spinal cord data. Spinal cord fMRI data from 27 participants were used for training of the network (135 runs for training and 81 runs for testing). We used average temporal signal-to-noise-ratio (tSNR) and Delta Variation Signal (DVARS) of raw and motion-corrected images to compare the outcome of DeepRetroMoco with sct_fmri_moco implemented in the spinal cord toolbox. The average tSNR in the cervical cord was significantly higher when DeepRetroMoco was used for motion correction compared to sct_fmri_moco method. Average DVARS was lower in images corrected by DeepRetroMoco than those corrected by sct_fmri_moco. The average processing time for DeepRetroMoco was also significantly shorter than sct_fmri_moco. Our results suggest that DeepRetroMoCo improves motion correction procedures in fMRI data acquired from the cervical spinal cord.

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Section: Discussionsupporting

confidence: 85%

DeepRetroMoCo: Deep neural network-based Retrospective Motion Correction Algorithm for Spinal Cord functional MRI

Mobarak-Abadi¹,

Mahmoudi-Aznave²,

Dehghani

et al. 2022

Preprint

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“…Instead, a series of registration algorithms more suited to biomedical images have been developed [23,30,50,83,92], further leading to several topology-preserving diffeomorphic extensions [8,12,20,96,98,105,89]. More recently, deep networks trained under either supervised [19,90,103] or unsuper-vised [11,26,29,57,60,73] registration objectives have emerged, simultaneously offering both greater modeling flexibility and accelerated inference performance.…”

Section: Related Workmentioning

confidence: 99%

Generative Adversarial Registration for Improved Conditional Deformable Templates

Dey¹,

Ren²,

Dalca³

et al. 2021

Preprint

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Deformable templates are essential to large-scale medical image registration, segmentation, and population analysis. Current conventional and deep network-based methods for template construction use only regularized registration objectives and often yield templates with blurry and/or anatomically implausible appearance, confounding downstream biomedical interpretation. We reformulate deformable registration and conditional template estimation as an adversarial game wherein we encourage realism in the moved templates with a generative adversarial registration framework conditioned on flexible image covariates. The resulting templates exhibit significant gain in specificity to attributes such as age and disease, better fit underlying group-wise spatiotemporal trends, and achieve improved sharpness and centrality. These improvements enable more accurate population modeling with diverse covariates for standardized downstream analyses and easier anatomical delineation for structures of interest.

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“…Challenges associated with generating ground truth data have recently led many researchers to develop unsupervised frameworks. Two recent works [4,17], presents an unsupervised learning-based image registration methods. Both propose a neural network consisting of a CNN and a spatial transformation function [10] that warps images to one another.…”

Section: Related Workmentioning

confidence: 99%

“…Both propose a neural network consisting of a CNN and a spatial transformation function [10] that warps images to one another. However, these two initial methods are only demonstrated on limited subsets, such as 3D sub-regions [17] or 2D slices [4], and support only small transformations [4]. All above methods were demonstrated on medical images.…”

Section: Related Workmentioning

confidence: 99%

Joint Unsupervised Infrared-RGB Video Registration and Fusion

Marouf¹,

Barras²,

Karaimer³

et al. 2021

lim

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We present a system to perform joint registration and fusion for RGB and Infrared (IR) video pairs. While RGB is related to human perception, IR is associated with heat. However, IR images often lack contour and texture information. The goal with the fusion of the visible and IR images is to obtain more information from them. This requires two completely matched images. However, classical methods assuming ideal imaging conditions fail to achieve satisfactory performance in actual cases. From the data-dependent modeling point of view, labeling the dataset is costly and impractical.In this context, we present a framework that tackles two challenging tasks. First, a video registration procedure that aims to align IR and RGB videos. Second, a fusion method brings all the essential information from the two video modalities to a single video. We evaluate our approach on a challenging dataset of RGB and IR video pairs collected for firefighters to handle their tasks effectively in challenging visibility conditions such as heavy smoke after a fire, see our project page.

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MDReg‐Net: Multi‐resolution diffeomorphic image registration using fully convolutional networks with deep self‐supervision

Cited by 26 publications

References 50 publications

DeepRetroMoCo: Deep neural network-based Retrospective Motion Correction Algorithm for Spinal Cord functional MRI

DeepRetroMoCo: Deep neural network-based Retrospective Motion Correction Algorithm for Spinal Cord functional MRI

Generative Adversarial Registration for Improved Conditional Deformable Templates

Joint Unsupervised Infrared-RGB Video Registration and Fusion

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