典型和改变发育过程中的新生儿大脑皮层缩放

Alexandra F Bonthrone, Daniel Cromb, Andrew Chew, Barat Gal-Er, Christopher Kelly, Shona Falconer, Tomoki Arichi, Kuberan Pushparajah, John Simpson, Mary A. Rutherford, Joseph V. Hajnal, Chiara Nosarti, A. David Edwards, Jonathan O'Muircheartaigh, Serena J. Counsell
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引用次数: 0

摘要

理论上推导出的缩放定律捕捉到了哺乳动物物种和成年人类快速膨胀的脑容量与皮层回旋之间的非线性关系。然而,这些定律在典型或病理大脑发育过程中的保留情况尚未得到全面评估。在这里,我们评估了新生儿大脑皮质厚度、表面积和皮质折叠的比例规律。我们还评估了捕捉大脑大小、形状和折叠过程的多元形态学术语。样本包括375名发育正常的婴儿、73名早产儿和107名患有先天性心脏病(CHD)的婴儿,他们都接受了脑磁共振成像(MRI)检查。我们的研究结果表明,发育正常的新生儿和患有先天性心脏病的新生儿遵循从哺乳动物、儿童和成人大脑中获得的皮质折叠缩放规律,该规律捕捉了暴露表面积、总表面积和皮质厚度之间的关系。在这些人群中,皮质折叠比例不受出生时的胎龄、扫描时的经后年龄、性别或多胎生育的影响。先天性心脏病的特点是多变量形态学术语捕获大小的独特减少,这表明先天性心脏病会影响大脑皮层的整体生长,但不会影响大脑皮层的折叠过程。与此相反,早产儿的特点是大脑皮层折叠比例和形状发生改变,这表明该人群大脑皮层折叠的发育程序被打乱。形状改变的程度与早产儿幼儿期的认知能力有关。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Cortical scaling of the neonatal brain in typical and altered development
Theoretically derived scaling laws capture the non-linear relationships between rapidly expanding brain volume and cortical gyrification across mammalian species and in adult humans. However, the preservation of these laws has not been comprehensively assessed in typical or pathological brain development. Here we assessed the scaling laws governing cortical thickness, surface area and cortical folding in the neonatal brain. We also assessed multivariate morphological terms that capture brain size, shape and folding processes. The sample consisted of 375 typically developing infants, 73 preterm infants and 107 infants with congenital heart disease (CHD) who underwent brain magnetic resonance imaging (MRI). Our results show that typically developing neonates and those with CHD follow the cortical folding scaling law obtained from mammalian brains, children and adults which captures the relationship between exposed surface area, total surface area and cortical thickness. Cortical folding scaling was not affected by gestational age at birth, postmenstrual age at scan, sex or multiple birth in these populations. CHD was characterized by a unique reduction in the multivariate morphological term capturing size, suggesting CHD affects cortical growth overall but not cortical folding processes. In contrast, preterm birth was characterized by altered cortical folding scaling and altered shape, suggesting the developmentally programmed processes of cortical folding are disrupted in this population. The degree of altered shape was associated with cognitive abilities in early childhood in preterm infants.
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