Mapping Population-based Structural Connectomes

Overview

Journal Neuroimage

Specialty Radiology

Date 2018 Jan 23

PMID 29355769

Citations 44

Authors

Zhengwu Zhang

Maxime Descoteaux

Jingwen Zhang

Gabriel Girard

Maxime Chamberland

David Dunson

Anuj Srivastava

Hongtu Zhu

Affiliations

Soon will be listed here.

Abstract

Advances in understanding the structural connectomes of human brain require improved approaches for the construction, comparison and integration of high-dimensional whole-brain tractography data from a large number of individuals. This article develops a population-based structural connectome (PSC) mapping framework to address these challenges. PSC simultaneously characterizes a large number of white matter bundles within and across different subjects by registering different subjects' brains based on coarse cortical parcellations, compressing the bundles of each connection, and extracting novel connection weights. A robust tractography algorithm and streamline post-processing techniques, including dilation of gray matter regions, streamline cutting, and outlier streamline removal are applied to improve the robustness of the extracted structural connectomes. The developed PSC framework can be used to reproducibly extract binary networks, weighted networks and streamline-based brain connectomes. We apply the PSC to Human Connectome Project data to illustrate its application in characterizing normal variations and heritability of structural connectomes in healthy subjects.

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