1. Mapping Genetic Topography of Cortical Thickness and Surface Area in Neonatal Brains.
- Author
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Ying Huang, Zhengwang Wu, Tengfei Li, Xifeng Wang, Ya Wang, Lei Xing, Hongtu Zhu, Weili Lin, Li Wang, Lei Guo, Gilmore, John H., and Gang Li
- Subjects
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GENE mapping , *SURFACE area , *CEREBRAL cortex , *TOPOGRAPHY , *GENETIC correlations , *MAGNETIC resonance , *NO-tillage - Abstract
Adult twin neuroimaging studies have revealed that cortical thickness (CT) and surface area (SA) are differentially influenced by genetic information, leading to their spatially distinct genetic patterning and topography. However, the postnatal origins of the genetic topography of CT and SA remain unclear, given the dramatic cortical development from neonates to adults. To fill this critical gap, this study unprecedentedly explored how genetic information differentially regulates the spatial topography of CT and SA in the neonatal brain by leveraging brain magnetic resonance (MR) images from 202 twin neonates with minimal influence by the complicated postnatal environmental factors. We capitalized on infant-dedicated computational tools and a data-driven spectral clustering method to parcellate the cerebral cortex into a set of distinct regions purely according to the genetic correlation of cortical vertices in terms of CT and SA, respectively, and accordingly created the first genetically informed cortical parcellation maps of neonatal brains. Both genetic parcellation maps exhibit bilaterally symmetric and hierarchical patterns, but distinct spatial layouts. For CT, regions with closer genetic relationships demonstrate an anterior- posterior (A-P) division, while for SA, regions with greater genetic proximity are typically within the same lobe. Certain genetically informed regions exhibit strong similarities between neonates and adults, with the most striking similarities in the medial surface in terms of SA, despite their overall substantial differences in genetic parcellation maps. These results greatly advance our understanding of the development of genetic influences on the spatial patterning of cortical morphology. [ABSTRACT FROM AUTHOR]
- Published
- 2023
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