Continuous representations of brain connectivity using spatial point processes

Moyer, Daniel; Gutman, Boris A.; Faskowitz, Joshua; Jahanshad, Neda; Thompson, Paul M.

doi:10.1016/j.media.2017.04.013

Cited by 19 publications

(27 citation statements)

References 46 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Fifth, in the present study, we compared two fiber clustering and cortical-parcellation-based strategies that are widely used but relatively traditional approaches. In the past few years, there have been methods designed to improve test-retest reproducibility for constructing cortical-parcellation-based connectomes by including additional pre-and/or postprocessing steps, for example, dilating gray matter regions (Zhang, Descoteaux, Zhang, et al, 2018), constructing continuous connectome matrices (Moyer, Gutman, Faskowitz, Jahanshad, & Thompson, 2017), and filtering out implausible fiber streamlines (Smith et al, 2015). A further study could include comparison of test-retest reproducibility between the fiber clustering and cortical-parcellation-based strategies with advanced processing.…”

Section: Discussionmentioning

confidence: 99%

Test–retest reproducibility of white matter parcellation using diffusion MRI tractography fiber clustering

Zhang

Norton

et al. 2019

Human Brain Mapping

View full text Add to dashboard Cite

There are two popular approaches for automated white matter parcellation using diffusion MRI tractography, including fiber clustering strategies that group white matter fibers according to their geometric trajectories and cortical‐parcellation‐based strategies that focus on the structural connectivity among different brain regions of interest. While multiple studies have assessed test–retest reproducibility of automated white matter parcellations using cortical‐parcellation‐based strategies, there are no existing studies of test–retest reproducibility of fiber clustering parcellation. In this work, we perform what we believe is the first study of fiber clustering white matter parcellation test–retest reproducibility. The assessment is performed on three test–retest diffusion MRI datasets including a total of 255 subjects across genders, a broad age range (5–82 years), health conditions (autism, Parkinson's disease and healthy subjects), and imaging acquisition protocols (three different sites). A comprehensive evaluation is conducted for a fiber clustering method that leverages an anatomically curated fiber clustering white matter atlas, with comparison to a popular cortical‐parcellation‐based method. The two methods are compared for the two main white matter parcellation applications of dividing the entire white matter into parcels (i.e., whole brain white matter parcellation) and identifying particular anatomical fiber tracts (i.e., anatomical fiber tract parcellation). Test–retest reproducibility is measured using both geometric and diffusion features, including volumetric overlap (wDice) and relative difference of fractional anisotropy. Our experimental results in general indicate that the fiber clustering method produced more reproducible white matter parcellations than the cortical‐parcellation‐based method.

show abstract

Section: Discussionmentioning

confidence: 99%

Test–retest reproducibility of white matter parcellation using diffusion MRI tractography fiber clustering

Zhang

Norton

et al. 2019

Human Brain Mapping

View full text Add to dashboard Cite

show abstract

“…However, the conductance values may not fit the definition of either streamlines or probability measures. As we have shown in Section 2, the proposed method can also enable the computation of voxel-wise and thus parcellationindependent connectivity (Moyer et al, 2017), which allows us to compute the connectivity between any pair of points in the white matter.…”

Section: Discussionmentioning

confidence: 99%

Quantification of Structural Brain Connectivity via a Conductance Model

Frau-Pascual

Fogarty

Fischl

et al. 2018

Preprint

View full text Add to dashboard Cite

Connectomics has proved promising in quantifying and understanding the effects of development, aging and an array of diseases on the brain. In this work, we propose a new structural connectivity measure from diffusion MRI that allows us to incorporate direct brain connections, as well as indirect ones that would not be otherwise accounted for by standard techniques and that may be key for the better understanding of function from structure. From our experiments on the Human Connectome Project dataset, we find that our measure of structural connectivity better correlates with functional connectivity than streamline tractography does, meaning that it provides new structural information related to function. Through additional experiments on the ADNI-2 dataset, we demonstrate the ability of this new measure to better discriminate different stages of Alzheimer's disease. Our findings suggest that this measure is useful in the study of the normal brain structure, and for quantifying the effects of disease on the brain structure.

show abstract

“…From such a representation, a "discrete" connectivity graph could be computed from any particular cortical parcellation P . We follow definitions from [8] and call P =…”

Section: Continuous Connectomementioning

confidence: 99%

“…We use construct continuous connetocmes of 400 subjects from the Human Connectome Project S900 release [13] following [8]. We use an icosahedral spehrical sampling, at a resolution of 10242 mesh vertices per hemisphere.…”

Section: Data Descriptionmentioning

confidence: 99%

Connectivity-Driven Brain Parcellation via Consensus Clustering

Kurmukov

Musabaeva

Denisova

et al. 2018

Connectomics in NeuroImaging

Self Cite

View full text Add to dashboard Cite

We present two related methods for deriving connectivitybased brain atlases from individual connectomes. The proposed methods exploit a previously proposed dense connectivity representation, termed continuous connectivity, by first performing graph-based hierarchical clustering of individual brains, and subsequently aggregating the individual parcellations into a consensus parcellation. The search for consensus minimizes the sum of cluster membership distances, effectively estimating a pseudo-Karcher mean of individual parcellations. We assess the quality of our parcellations using (1) Kullback-Liebler and Jensen-Shannon divergence with respect to the dense connectome representation, (2) interhemispheric symmetry, and (3) performance of the simplified connectome in a biological sex classification task. We find that the parcellation based-atlas computed using a greedy search at a hierarchical depth 3 outperforms all other parcellation-based atlases as well as the standard Dessikan-Killiany anatomical atlas in all three assessments. arXiv:1808.04262v1 [q-bio.NC]

show abstract

Continuous representations of brain connectivity using spatial point processes

Cited by 19 publications

References 46 publications

Test–retest reproducibility of white matter parcellation using diffusion MRI tractography fiber clustering

Test–retest reproducibility of white matter parcellation using diffusion MRI tractography fiber clustering

Quantification of Structural Brain Connectivity via a Conductance Model

Connectivity-Driven Brain Parcellation via Consensus Clustering

Contact Info

Product

Resources

About