SurfFlow: A Flow-Based Approach for Rapid and Accurate Cortical Surface Reconstruction from Infant Brain MRI.

Xiaoyang Chen, Junjie Zhao, Siyuan Liu, Sahar Ahmad, Pew-Thian Yap
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Abstract

The infant brain undergoes rapid changes in volume, shape, and structural organization during the first postnatal year. Accurate cortical surface reconstruction (CSR) is essential for understanding rapid changes in cortical morphometry during early brain development. However, existing CSR methods, designed for adult brain MRI, fall short in reconstructing cortical surfaces from infant MRI, owing to the poor tissue contrasts, partial volume effects, and rapid changes in cortical folding patterns. Here, we introduce an infant-centric CSR method in light of these challenges. Our method, SurfFlow, utilizes three seamlessly connected deformation blocks to sequentially deform an initial template mesh to target cortical surfaces. Remarkably, our method can rapidly reconstruct a high-resolution cortical surface mesh with 360k vertices in approximately one second. Performance evaluation based on an MRI dataset of infants 0 to 12 months of age indicates that SurfFlow significantly reduces geometric errors and substantially improves mesh regularity compared with state-of-the-art deep learning approaches.

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SurfFlow:一种基于流的方法,用于从婴儿脑磁共振成像中快速、准确地重建皮质表面。
在出生后的第一年,婴儿大脑的体积、形状和结构组织会发生快速变化。准确的皮质表面重建(CSR)对于了解大脑早期发育过程中皮质形态的快速变化至关重要。然而,由于组织对比度差、部分体积效应和皮质折叠模式的快速变化,现有的针对成人大脑 MRI 设计的 CSR 方法在重建婴儿 MRI 的皮质表面方面存在不足。鉴于这些挑战,我们在此介绍一种以婴儿为中心的 CSR 方法。我们的方法--SurfFlow--利用三个无缝连接的变形块,按顺序将初始模板网格变形为目标皮质表面。值得注意的是,我们的方法可以在大约一秒钟内快速重建 360k 个顶点的高分辨率皮质表面网格。基于 0 到 12 个月婴儿核磁共振成像数据集的性能评估表明,与最先进的深度学习方法相比,SurfFlow 能显著减少几何误差,并大幅提高网格的规则性。
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