MUSE: MUlti-atlas region Segmentation utilizing Ensembles of registration algorithms and parameters, and locally optimal atlas selection

Atlas-based automated anatomical labeling is a fundamental tool in medical image segmentation, as it defines regions of interest for subsequent analysis of structural and functional image data. The extensive investigation of multi-atlas warping and fusion techniques over the past 5 or more years has...

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Bibliographic Details
Published in:NeuroImage (Orlando, Fla.) Fla.), 2016-02, Vol.127, p.186-195
Main Authors: Doshi, Jimit, Erus, Guray, Ou, Yangming, Resnick, Susan M., Gur, Ruben C., Gur, Raquel E., Satterthwaite, Theodore D., Furth, Susan, Davatzikos, Christos
Format: Article
Language:English
Subjects:
Accuracy
Algorithms
Anatomy, Artistic
Atlases as Topic
Brain - anatomy & histology
Brain Mapping - methods
Datasets
Humans
Image Processing, Computer-Assisted - methods
Label fusion
Methods
MRI
Multi-atlas segmentation
Pattern Recognition, Automated - methods
Registration
ROI
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Summary:Atlas-based automated anatomical labeling is a fundamental tool in medical image segmentation, as it defines regions of interest for subsequent analysis of structural and functional image data. The extensive investigation of multi-atlas warping and fusion techniques over the past 5 or more years has clearly demonstrated the advantages of consensus-based segmentation. However, the common approach is to use multiple atlases with a single registration method and parameter set, which is not necessarily optimal for every individual scan, anatomical region, and problem/data-type. Different registration criteria and parameter sets yield different solutions, each providing complementary information. Herein, we present a consensus labeling framework that generates a broad ensemble of labeled atlases in target image space via the use of several warping algorithms, regularization parameters, and atlases. The label fusion integrates two complementary sources of information: a local similarity ranking to select locally optimal atlases and a boundary modulation term to refine the segmentation consistently with the target image's intensity profile. The ensemble approach consistently outperforms segmentations using individual warping methods alone, achieving high accuracy on several benchmark datasets. The MUSE methodology has been used for processing thousands of scans from various datasets, producing robust and consistent results. MUSE is publicly available both as a downloadable software package, and as an application that can be run on the CBICA Image Processing Portal (https://ipp.cbica.upenn.edu), a web based platform for remote processing of medical images. •A new multiatlas segmentation framework using a broad ensemble of labeled templates•Combines different atlases, warping algorithms, and regularization parameters•Uses an adaptive fusion strategy through local similarity weighting and intensity based refinement•Ensemble approach provides robustness to image variations and produces accurate segmentations.
ISSN:1053-8119
1095-9572
DOI:10.1016/j.neuroimage.2015.11.073