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Discovering cortical sulcal folding patterns in neonates using large-scale dataset

Authors
Meng, YuLi, GangWang, LiLin, WeiliGilmore, John H.Shen, Dinggang
Issue Date
9월-2018
Publisher
WILEY
Keywords
cortical surface; neonatal brain; sulcal folding pattern; sulcal pit
Citation
HUMAN BRAIN MAPPING, v.39, no.9, pp.3625 - 3635
Indexed
SCIE
SCOPUS
Journal Title
HUMAN BRAIN MAPPING
Volume
39
Number
9
Start Page
3625
End Page
3635
URI
https://scholar.korea.ac.kr/handle/2021.sw.korea/73596
DOI
10.1002/hbm.24199
ISSN
1065-9471
Abstract
The folding of the human cerebral cortex is highly complex and variable across individuals, but certain common major patterns of cortical folding do exist. Mining such common patterns of cortical folding is of great importance in understanding the inter-individual variability of cortical folding and their relationship with cognitive functions and brain disorders. As primary cortical folds are mainly genetically influenced and are well established at term birth, neonates with minimal exposure to the complicated postnatal environmental influences are ideal candidates for mining the major patterns of cortical folding. In this paper, we propose a sulcal-pit-based method to discover the major sulcal patterns of cortical folding. In our method, first, the sulcal pattern is characterized by the spatial distribution of sulcal pits, which are the locally deepest points in cortical sulci. Since deep sulcal pits are genetically related, relatively consistent across individuals, and also stable during brain development, they are well suited for representing and characterizing the sulcal patterns. Then, the similarity between the distributions of sulcal pits is measured from the spatial, geometrical, and topological points of view. Next, a comprehensive similarity matrix is constructed for the whole dataset by adaptively fusing these measurements together, thus capturing both their common and complementary information. Finally, leveraging the similarity matrix, a hierarchical affinity propagation algorithm is used to group similar sulcal folding patterns together. The proposed method has been applied to 677 neonatal brains, and revealed multiple distinct and meaningful sulcal patterns in the central sulcus, superior temporal sulcus, and cingulate sulcus.
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