Automatic DTI-based parcellation of the corpus callosum through the watershed transform

Rittner, Letícia; Freitas, Pedro; Appenzeller, Simone; Lotufo, Roberto de Alencar

doi:10.1590/rbeb.2014.012

Cited by 14 publications

(9 citation statements)

References 32 publications

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“…The inconsistency may stem from the use of the mcDESPOT, an approach that has been criticized for confounding magnetization transfer effects (Zhang et al 2015) and the influence of water exchange between the different compartments (Lankford and Does 2013;Does 2018;West et al 2019). In addition, as expected, conventional DTI-derived indicators also evinced different patterns across the CC in healthy individuals (Hasan et al 2005;Hofer and Frahm 2006;Rittner et al 2014).…”

Section: Regional Differences In Callosal Microstructuresupporting

confidence: 78%

Microstructure of Human Corpus Callosum across the Lifespan: Regional Variations in Axon Caliber, Density, and Myelin Content

et al. 2020

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The myeloarchitecture of the corpus callosum (CC) is characterized as a mosaic of distinct differences in fiber density of small- and large-diameter axons along the anterior–posterior axis; however, regional and age differences across the lifespan are not fully understood. Using multiecho T2 magnetic resonance imaging combined with multi-T2 fitting, the myelin water fraction (MWF) and geometric-mean of the intra-/extracellular water T2 (geomT2IEW) in 395 individuals (7–85 years; 41% males) were examined. The approach was validated where regional patterns along the CC closely resembled the histology; MWF matched mean axon diameter and geomT2IEW mirrored the density of large-caliber axons. Across the lifespan, MWF exhibited a quadratic association with age in all 10 CC regions with evidence of a positive linear MWF-age relationship among younger participants and minimal age differences in the remainder of the lifespan. Regarding geomT2IEW, a significant linear age × region interaction reflected positive linear age dependence mostly prominent in the regions with the highest density of small-caliber fibers—genu and splenium. In all, these two indicators characterize distinct attributes that are consistent with histology, which is a first. In addition, these results conform to rapid developmental progression of CC myelination leveling in middle age as well as age-related degradation of axon sheaths in older adults.

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Section: Regional Differences In Callosal Microstructuresupporting

confidence: 78%

Microstructure of Human Corpus Callosum across the Lifespan: Regional Variations in Axon Caliber, Density, and Myelin Content

et al. 2020

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“…We notice that geometric methods allow only to divide the CC into the same regions among all subjects without considering the human and individual brain features between different subjects. On the second hand, differently to geometric parcellation methods, Rittner proposed a data-driven method based on the Watershed technique [15]. This method is composed of four steps.…”

Section: Related Workmentioning

confidence: 99%

“…Despite its simplicity, SLIC has been demonstrated to be effective in various computer vision applications [14]. -The subdivision process of the proposed method is fully automatic and it is the second study that proposed a non-geometric analysis for the CC parcels, to the best of our knowledge [15]. Although it is based only on the MRI data of each analyzed subject, with no parameter adjusting, the proposed method proved quantitatively its superiority over state-of-the-art methods.…”

Section: Introductionmentioning

confidence: 99%

Unsupervised Method Based on Superpixel Segmentation for Corpus Callosum Parcellation in MRI Scans

Jlassi

Barhoumi

Maktouf

2020

Lecture Notes in Computer Science

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In this paper, we introduce an unsupervised method for the parcellation of the Corpus Callosum (CC) from MRI images. Since there are no visible landmarks within the structure that explicit its parcels, non-geometric CC parcellation is a challenging task especially that almost of proposed methods are geometric or data-based. In fact, in order to subdivide the CC from brain sagittal MRI scans, we adopt the probabilistic neural network as a clustering technique. Then, we use a cluster validity measure based on the maximum entropy (Vmep) to obtain the optimal number of classes. After that, we obtain the isolated CC that we parcel automatically using SLIC (Simple Linear Iterative Clustering) as superpixel segmentation technique. The obtained results on two challenging public datasets prove the performance of the proposed method against geometric methods from the state of the art. Indeed, as best as we know, it is the first work that investigates the validation of a CC parcellation method on ground-truth datasets using many objective metrics.

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“…Following these brain templates and the raising necessity to others MR imaging modalities, the Diffusion Tensor Imaging (DTI) was also intensively studied to add more possibilities for the white matter brain studies (Alves et al, 2012;Itagiba et al, 2010;Miraldi et al, 2013;Rittner et al, 2014). In the past, the lack of white matter information is understandable due to a homogeneous appearance in conventional MRI, as well as in histology preparations Mori et al, 2008).…”

Section: Introductionmentioning

confidence: 99%

Populational brain models of diffusion tensor imaging for statistical analysis: a complementary information in common space

Filho

Murta

2017

Res. Biomed. Eng.

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Introduction: The search for human brain templates has been progressing in the past decades and in order to understand disease patterns a need for a standard diffusion tensor imaging (DTI) dataset was raised. For this purposes, some DTI templates were developed which assist group analysis studies. In this study, complementary information to the most commonly used DTI template is proposed in order to offer a patient-specific statistical analysis on diffusion-weighted data. Methods: 131 normal subjects were used to reconstruct a population-averaged template. After image pre processing, reconstruction and diagonalization, the eigenvalues and eigenvectors were used to reconstruct the quantitative DTI maps, namely fractional anisotropy (FA), mean diffusivity (MD), relative anisotropy (RA), and radial diffusivity (RD). The mean absolute error (MAE) was calculated using a voxel-wise procedure, which informs the global error regarding the mean intensity value for each quantitative map. This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.How to cite this article: Senra ACS Fo, Murta LO Jr. Populational brain models of diffusion tensor imaging for statistical analysis: a complementary information in common space. Res Biomed Eng. 2017; 33(3):269-275.

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Automatic DTI-based parcellation of the corpus callosum through the watershed transform

Cited by 14 publications

References 32 publications

Microstructure of Human Corpus Callosum across the Lifespan: Regional Variations in Axon Caliber, Density, and Myelin Content

Microstructure of Human Corpus Callosum across the Lifespan: Regional Variations in Axon Caliber, Density, and Myelin Content

Unsupervised Method Based on Superpixel Segmentation for Corpus Callosum Parcellation in MRI Scans

Populational brain models of diffusion tensor imaging for statistical analysis: a complementary information in common space

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