Role of Data-driven Regional Growth Model in Shaping Brain Folding Patterns

Jixin Hou, Zhengwang Wu, Xianyan Chen, Dajiang Zhu, Tianming Liu, Gang Li, Xianqiao Wang
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Abstract

The surface morphology of the developing mammalian brain is crucial for understanding brain function and dysfunction. Computational modeling offers valuable insights into the underlying mechanisms for early brain folding. While previous studies generally assume uniform growth, recent findings indicate significant regional variations in brain tissue growth. However, the role of these variations in cortical development remains unclear. In this study, we explored how regional cortical growth affects brain folding patterns. We first developed growth models for typical cortical regions using ML-assisted symbolic regression, based on longitudinal data from over 1,000 infant MRI scans that captured cortical surface area and thickness during perinatal and postnatal brains development. These models were subsequently integrated into computational software to simulate cortical development with anatomically realistic geometric models. We quantified the resulting folding patterns using metrics such as mean curvature, sulcal depth, and gyrification index. Our results demonstrate that regional growth models generate complex brain folding patterns that more closely match actual brains structures, both quantitatively and qualitatively, compared to uniform growth models. Growth magnitude plays a dominant role in shaping folding patterns, while growth trajectory has a minor influence. Moreover, multi-region models better capture the intricacies of brain folding than single-region models. Our results underscore the necessity and importance of incorporating regional growth heterogeneity into brain folding simulations, which could enhance early diagnosis and treatment of cortical malformations and neurodevelopmental disorders such as epilepsy and autism.
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数据驱动的区域生长模型在塑造大脑折叠模式中的作用
发育中哺乳动物大脑的表面形态对于了解大脑功能和功能障碍至关重要。计算建模为早期大脑折叠的内在机制提供了宝贵的见解。以往的研究通常假定大脑是均匀生长的,但最近的研究结果表明,大脑组织的生长存在明显的区域性差异。然而,这些变化在大脑皮层发育中的作用仍不清楚。在这项研究中,我们探讨了区域性皮质生长如何影响大脑褶皱模式。我们首先利用 ML 辅助符号回归,基于 1000 多例婴儿核磁共振扫描的纵向数据,建立了典型皮质区域的生长模型,这些数据捕捉了围产期和出生后大脑发育过程中皮质的表面积和厚度。这些模型随后被整合到计算软件中,以解剖学上真实的几何模型模拟大脑皮层的发育过程。我们使用平均曲率、沟深度和回旋指数等指标对由此产生的褶皱模式进行了量化。我们的研究结果表明,与均匀生长模型相比,区域生长模型产生的复杂大脑褶皱模式在数量和质量上都更接近实际大脑结构。生长幅度在塑造褶皱模式中起主要作用,而生长轨迹的影响较小。此外,与单区域模型相比,多区域模型能更好地捕捉大脑折叠的复杂性。我们的研究结果凸显了将区域生长异质性纳入大脑折叠模拟的必要性和重要性,这可以提高对皮层畸形和神经发育疾病(如癫痫和自闭症)的早期诊断和治疗。
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