A populational connection distribution map for the whole brain white matter reveals ordered cortical wiring in the space of white matteropen access
- Authors
- Lee, Dongha; Park, Hae-Jeong
- Issue Date
- Jul-2022
- Publisher
- Academic Press
- Citation
- NeuroImage, v.254
- Journal Title
- NeuroImage
- Volume
- 254
- URI
- http://scholarworks.bwise.kr/kbri/handle/2023.sw.kbri/225
- DOI
- 10.1016/j.neuroimage.2022.119167
- ISSN
- 1053-8119
- Abstract
- The white matter in the brain is composed of neural fibers that wire the cortical and subcortical brain systems. Considering the complexity in terms of interconnections of many neural populations within the narrow space surrounded by the folding walls of the gray matter, the brain requires a certain way of structured wiring. To explore the three-dimensional organization of wiring in an accessible manner, we focused on voxel-level wiring patterns in the white matter according to cortical distributions in which each voxel mediates the wiring. We constructed a voxel-wise connection distribution map from the whole white matter voxels to 360 cortical regions using probabilistic tractography of the 100 diffusion imaging data in the Human Connectome Project. We then explored the spatial organization of the fiber bundles at the white matter voxels in terms of the maximal and second maximal cortical connection labels and the local gradient and entropy of cortical connection density using the population connection distribution map. We presented dominant cortical connection labels, local gradient, and connection entropy for the most representative white matter regions, including the internal capsule, external capsule, corpus callosum, cingulum bundle, and uncinate fascicles, most of which were introduced in the current study. Those major tracts showed a gradient organization of connection distributions for individual voxels. This organized pattern, as reflected in the whole brain connection distribution map, could be established to optimize wiring in the entire brain within the physical space of the white matter.
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