AngioMoCo: Learning-based Motion Correction in Cerebral Digital
Subtraction Angiography
- URL: http://arxiv.org/abs/2310.05445v1
- Date: Mon, 9 Oct 2023 06:42:43 GMT
- Title: AngioMoCo: Learning-based Motion Correction in Cerebral Digital
Subtraction Angiography
- Authors: Ruisheng Su, Matthijs van der Sluijs, Sandra Cornelissen, Wim van
Zwam, Aad van der Lugt, Wiro Niessen, Danny Ruijters, Theo van Walsum, and
Adrian Dalca
- Abstract summary: Cerebral X-ray digital subtraction angiography (DSA) is the standard imaging technique for visualizing blood flow and guiding endovascular treatments.
The quality of DSA is often negatively impacted by body motion during acquisition, leading to decreased diagnostic value.
We present AngioMoCo, a learning-based framework that generates motion-compensated DSA sequences from X-ray angiography.
- Score: 1.8537989329832776
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Cerebral X-ray digital subtraction angiography (DSA) is the standard imaging
technique for visualizing blood flow and guiding endovascular treatments. The
quality of DSA is often negatively impacted by body motion during acquisition,
leading to decreased diagnostic value. Time-consuming iterative methods address
motion correction based on non-rigid registration, and employ sparse key points
and non-rigidity penalties to limit vessel distortion. Recent methods alleviate
subtraction artifacts by predicting the subtracted frame from the corresponding
unsubtracted frame, but do not explicitly compensate for motion-induced
misalignment between frames. This hinders the serial evaluation of blood flow,
and often causes undesired vasculature and contrast flow alterations, leading
to impeded usability in clinical practice. To address these limitations, we
present AngioMoCo, a learning-based framework that generates motion-compensated
DSA sequences from X-ray angiography. AngioMoCo integrates contrast extraction
and motion correction, enabling differentiation between patient motion and
intensity changes caused by contrast flow. This strategy improves registration
quality while being substantially faster than iterative elastix-based methods.
We demonstrate AngioMoCo on a large national multi-center dataset (MR CLEAN
Registry) of clinically acquired angiographic images through comprehensive
qualitative and quantitative analyses. AngioMoCo produces high-quality
motion-compensated DSA, removing motion artifacts while preserving contrast
flow. Code is publicly available at https://github.com/RuishengSu/AngioMoCo.
Related papers
- Beyond the Eye: A Relational Model for Early Dementia Detection Using Retinal OCTA Images [42.75763279888966]
We present a novel PolarNet+ that uses retinal optical coherence tomography angiography ( OCTA) to discriminate early-onset Alzheimer's disease (AD) and mild cognitive impairment (MCI) subjects from controls.
Our method first maps OCTA images from Cartesian coordinates to polar coordinates, allowing approximate sub-region calculation.
We then introduce a multi-view module to serialize and analyze the images along three dimensions for comprehensive, clinically useful information extraction.
arXiv Detail & Related papers (2024-08-09T15:10:34Z) - IM-MoCo: Self-supervised MRI Motion Correction using Motion-Guided Implicit Neural Representations [2.2265038612930663]
Motion artifacts in Magnetic Resonance Imaging (MRI) arise due to relatively long acquisition times.
Traditional motion correction methods often fail to address severe motion, leading to distorted and unreliable results.
We present an instance-wise motion correction pipeline that leverages motion-guided Implicit Neural Representations (INRs)
Our method improves classification outcomes by at least $+1.5$ accuracy percentage points compared to motion-corrupted images.
arXiv Detail & Related papers (2024-07-03T10:14:33Z) - LaMoD: Latent Motion Diffusion Model For Myocardial Strain Generation [5.377722774297911]
We introduce a novel Latent Motion Diffusion model (LaMoD) to predict highly accurate DENSE motions from standard CMR videos.
Experimental results demonstrate that our proposed method, LaMoD, significantly improves the accuracy of motion analysis in standard CMR images.
arXiv Detail & Related papers (2024-07-02T12:54:32Z) - Attention-aware non-rigid image registration for accelerated MR imaging [10.47044784972188]
We introduce an attention-aware deep learning-based framework that can perform non-rigid pairwise registration for fully sampled and accelerated MRI.
We extract local visual representations to build similarity maps between the registered image pairs at multiple resolution levels.
We demonstrate that our model derives reliable and consistent motion fields across different sampling trajectories.
arXiv Detail & Related papers (2024-04-26T14:25:07Z) - TAI-GAN: A Temporally and Anatomically Informed Generative Adversarial
Network for early-to-late frame conversion in dynamic cardiac PET inter-frame
motion correction [15.380659401728735]
We propose a novel method called Temporally and Anatomically Informed Generative Adrial Network (TAI-GAN) to convert early frames into those with tracer distribution similar to the last reference frame.
Our proposed method was evaluated on a clinical 82-Rb PET dataset, and the results show that our TAI-GAN can produce converted early frames with high image quality, comparable to the real reference frames.
arXiv Detail & Related papers (2024-02-14T20:39:07Z) - On Sensitivity and Robustness of Normalization Schemes to Input
Distribution Shifts in Automatic MR Image Diagnosis [58.634791552376235]
Deep Learning (DL) models have achieved state-of-the-art performance in diagnosing multiple diseases using reconstructed images as input.
DL models are sensitive to varying artifacts as it leads to changes in the input data distribution between the training and testing phases.
We propose to use other normalization techniques, such as Group Normalization and Layer Normalization, to inject robustness into model performance against varying image artifacts.
arXiv Detail & Related papers (2023-06-23T03:09:03Z) - Motion Correction and Volumetric Reconstruction for Fetal Functional
Magnetic Resonance Imaging Data [3.690756997172894]
Motion correction is an essential preprocessing step in functional Magnetic Resonance Imaging (fMRI) of the fetal brain.
Current motion correction approaches for fetal fMRI choose a single 3D volume from a specific acquisition timepoint.
We propose a novel framework, which estimates a high-resolution reference volume by using outlier-robust motion correction.
arXiv Detail & Related papers (2022-02-11T19:11:16Z) - Improved Slice-wise Tumour Detection in Brain MRIs by Computing
Dissimilarities between Latent Representations [68.8204255655161]
Anomaly detection for Magnetic Resonance Images (MRIs) can be solved with unsupervised methods.
We have proposed a slice-wise semi-supervised method for tumour detection based on the computation of a dissimilarity function in the latent space of a Variational AutoEncoder.
We show that by training the models on higher resolution images and by improving the quality of the reconstructions, we obtain results which are comparable with different baselines.
arXiv Detail & Related papers (2020-07-24T14:02:09Z) - A Novel Approach for Correcting Multiple Discrete Rigid In-Plane Motions
Artefacts in MRI Scans [63.28835187934139]
We propose a novel method for removing motion artefacts using a deep neural network with two input branches.
The proposed method can be applied to artefacts generated by multiple movements of the patient.
arXiv Detail & Related papers (2020-06-24T15:25:11Z) - Segmentation of the Myocardium on Late-Gadolinium Enhanced MRI based on
2.5 D Residual Squeeze and Excitation Deep Learning Model [55.09533240649176]
The aim of this work is to develop an accurate automatic segmentation method based on deep learning models for the myocardial borders on LGE-MRI.
A total number of 320 exams (with a mean number of 6 slices per exam) were used for training and 28 exams used for testing.
The performance analysis of the proposed ensemble model in the basal and middle slices was similar as compared to intra-observer study and slightly lower at apical slices.
arXiv Detail & Related papers (2020-05-27T20:44:38Z) - Multifold Acceleration of Diffusion MRI via Slice-Interleaved Diffusion
Encoding (SIDE) [50.65891535040752]
We propose a diffusion encoding scheme, called Slice-Interleaved Diffusion.
SIDE, that interleaves each diffusion-weighted (DW) image volume with slices encoded with different diffusion gradients.
We also present a method based on deep learning for effective reconstruction of DW images from the highly slice-undersampled data.
arXiv Detail & Related papers (2020-02-25T14:48:17Z)
This list is automatically generated from the titles and abstracts of the papers in this site.
This site does not guarantee the quality of this site (including all information) and is not responsible for any consequences.