Related papers: SynthStrip: Skull-Stripping for Any Brain Image

SynthStrip: Skull-Stripping for Any Brain Image

URL: http://arxiv.org/abs/2203.09974v1
Date: Fri, 18 Mar 2022 14:08:20 GMT
Title: SynthStrip: Skull-Stripping for Any Brain Image
Authors: Andrew Hoopes, Jocelyn S. Mora, Adrian V. Dalca, Bruce Fischl, Malte Hoffmann
Abstract summary: We introduce SynthStrip, a rapid, learning-based brain-extraction tool. By leveraging anatomical segmentations, SynthStrip generates a synthetic training dataset with anatomies, intensity distributions, and artifacts that far exceed the realistic range of medical images. We show substantial improvements in accuracy over popular skull-stripping baselines - all with a single trained model.
Score: 7.846209440615028
License: http://creativecommons.org/licenses/by/4.0/
Abstract: The removal of non-brain signal from magnetic resonance imaging (MRI) data, known as skull-stripping, is an integral component of many neuroimage analysis streams. Despite their abundance, popular classical skull-stripping methods are usually tailored to images with specific acquisition properties, namely near-isotropic resolution and T1-weighted (T1w) MRI contrast, which are prevalent in research settings. As a result, existing tools tend to adapt poorly to other image types, such as stacks of thick slices acquired with fast spin-echo (FSE) MRI that are common in the clinic. While learning-based approaches for brain extraction have gained traction in recent years, these methods face a similar burden, as they are only effective for image types seen during the training procedure. To achieve robust skull-stripping across a landscape of protocols, we introduce SynthStrip, a rapid, learning-based brain-extraction tool. By leveraging anatomical segmentations to generate an entirely synthetic training dataset with anatomies, intensity distributions, and artifacts that far exceed the realistic range of medical images, SynthStrip learns to successfully generalize to a variety of real acquired brain images, removing the need for training data with target contrasts. We demonstrate the efficacy of SynthStrip for a diverse set of image acquisitions and resolutions across subject populations, ranging from newborn to adult. We show substantial improvements in accuracy over popular skull-stripping baselines - all with a single trained model. Our method and labeled evaluation data are available at https://w3id.org/synthstrip.

Related papers

Unifying Subsampling Pattern Variations for Compressed Sensing MRI with Neural Operators [72.79532467687427]
Compressed Sensing MRI reconstructs images of the body's internal anatomy from undersampled and compressed measurements. Deep neural networks have shown great potential for reconstructing high-quality images from highly undersampled measurements. We propose a unified model that is robust to different subsampling patterns and image resolutions in CS-MRI.
arXiv Detail & Related papers (2024-10-05T20:03:57Z)
Towards General Text-guided Image Synthesis for Customized Multimodal Brain MRI Generation [51.28453192441364]
Multimodal brain magnetic resonance (MR) imaging is indispensable in neuroscience and neurology. Current MR image synthesis approaches are typically trained on independent datasets for specific tasks. We present TUMSyn, a Text-guided Universal MR image Synthesis model, which can flexibly generate brain MR images.
arXiv Detail & Related papers (2024-09-25T11:14:47Z)
Psychometry: An Omnifit Model for Image Reconstruction from Human Brain Activity [60.983327742457995]
Reconstructing the viewed images from human brain activity bridges human and computer vision through the Brain-Computer Interface. We devise Psychometry, an omnifit model for reconstructing images from functional Magnetic Resonance Imaging (fMRI) obtained from different subjects.
arXiv Detail & Related papers (2024-03-29T07:16:34Z)
Segment anything model (SAM) for brain extraction in fMRI studies [0.0]
We will use the segment anything model (SAM) for neuroimaging brain segmentation by removing skull artifacts. The results of the experiments showed promising results that explore using automated segmentation algorithms for neuroimaging without the need to train on custom medical imaging dataset.
arXiv Detail & Related papers (2024-01-09T06:25:09Z)
FAST-AID Brain: Fast and Accurate Segmentation Tool using Artificial Intelligence Developed for Brain [0.8376091455761259]
A novel deep learning method is proposed for fast and accurate segmentation of the human brain into 132 regions. The proposed model uses an efficient U-Net-like network and benefits from the intersection points of different views and hierarchical relations. The proposed method can be applied to brain MRI data including skull or any other artifacts without preprocessing the images or a drop in performance.
arXiv Detail & Related papers (2022-08-30T16:06:07Z)
Subject-Specific Lesion Generation and Pseudo-Healthy Synthesis for Multiple Sclerosis Brain Images [1.7328025136996081]
We present a novel generative method for modelling the local lesion characteristics. It can generate synthetic lesions on healthy images and synthesize subject-specific pseudo-healthy images from pathological images. The proposed method can be used as a data augmentation module to generate synthetic images for training brain image segmentation networks.
arXiv Detail & Related papers (2022-08-03T15:12:55Z)
Robust Segmentation of Brain MRI in the Wild with Hierarchical CNNs and no Retraining [1.0499611180329802]
Retrospective analysis of brain MRI scans acquired in the clinic has the potential to enable neuroimaging studies with sample sizes much larger than those found in research datasets. Recent advances in convolutional neural networks (CNNs) and domain randomisation for image segmentation may enable morphometry of clinical MRI at scale. We show that SynthSeg is generally robust, but frequently falters on scans with low signal-to-noise ratio or poor tissue contrast. We propose SynthSeg+, a novel method that greatly mitigates these problems using a hierarchy of conditional segmentation and denoising CNNs.
arXiv Detail & Related papers (2022-03-03T19:18:28Z)
Cross-Modality Neuroimage Synthesis: A Survey [71.27193056354741]
Multi-modality imaging improves disease diagnosis and reveals distinct deviations in tissues with anatomical properties. The existence of completely aligned and paired multi-modality neuroimaging data has proved its effectiveness in brain research. An alternative solution is to explore unsupervised or weakly supervised learning methods to synthesize the absent neuroimaging data.
arXiv Detail & Related papers (2022-02-14T19:29:08Z)
Incremental Cross-view Mutual Distillation for Self-supervised Medical CT Synthesis [88.39466012709205]
This paper builds a novel medical slice to increase the between-slice resolution. Considering that the ground-truth intermediate medical slices are always absent in clinical practice, we introduce the incremental cross-view mutual distillation strategy. Our method outperforms state-of-the-art algorithms by clear margins.
arXiv Detail & Related papers (2021-12-20T03:38:37Z)
SynthMorph: learning contrast-invariant registration without acquired images [8.0963891430422]
We introduce a strategy for learning image registration without acquired imaging data. We show that this strategy enables robust and accurate registration of arbitrary MRI contrasts.
arXiv Detail & Related papers (2020-04-21T20:29:39Z)
Pathological Retinal Region Segmentation From OCT Images Using Geometric Relation Based Augmentation [84.7571086566595]
We propose improvements over previous GAN-based medical image synthesis methods by jointly encoding the intrinsic relationship of geometry and shape. The proposed method outperforms state-of-the-art segmentation methods on the public RETOUCH dataset having images captured from different acquisition procedures.
arXiv Detail & Related papers (2020-03-31T11:50:43Z)

This list is automatically generated from the titles and abstracts of the papers in this site.