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The role of cortical structural variance in deep learning-based prediction of fetal brain ageopen access

Authors
Kwon, HyeokjinYou, SungminYun, Hyuk JinJeong, SeungyoonDe Leon Barba, Anette PaulinaAguilar, Marisol Elizabeth LemusVergara, Pablo JaquezDavila, Sofia UrosaGrant, P. EllenLee, Jong-MinIm, Kiho
Issue Date
May-2024
Publisher
Frontiers Media S.A.
Keywords
magnetic resonance imaging; deep learning; fetal brain age; cortical surface; sulcal pattern
Citation
Frontiers in Neuroscience, v.18, pp 1 - 10
Pages
10
Indexed
SCIE
SCOPUS
Journal Title
Frontiers in Neuroscience
Volume
18
Start Page
1
End Page
10
URI
https://scholarworks.bwise.kr/hanyang/handle/2021.sw.hanyang/197480
DOI
10.3389/fnins.2024.1411334
ISSN
1662-4548
1662-453X
Abstract
Background: Deep-learning-based brain age estimation using magnetic resonance imaging data has been proposed to identify abnormalities in brain development and the risk of adverse developmental outcomes in the fetal brain. Although saliency and attention activation maps have been used to understand the contribution of different brain regions in determining brain age, there has been no attempt to explain the influence of shape-related cortical structural features on the variance of predicted fetal brain age. Methods: We examined the association between the predicted brain age difference (PAD: predicted brain age-chronological age) from our convolution neural networks-based model and global and regional cortical structural measures, such as cortical volume, surface area, curvature, gyrification index, and folding depth, using regression analysis. Results: Our results showed that global brain volume and surface area were positively correlated with PAD. Additionally, higher cortical surface curvature and folding depth led to a significant increase in PAD in specific regions, including the perisylvian areas, where dramatic agerelated changes in folding structures were observed in the late second trimester. Furthermore, PAD decreased with disorganized sulcal area patterns, suggesting that the interrelated arrangement and areal patterning of the sulcal folds also significantly affected the prediction of fetal brain age. Conclusion: These results allow us to better understand the variance in deep learning-based fetal brain age and provide insight into the mechanism of the fetal brain age prediction model.
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