TopoFit: Rapid Reconstruction of Topologically-Correct Cortical Surfaces

Overview

Journal Proc Mach Learn Res

Date 2023 May 23

PMID 37220495

Authors

Andrew Hoopes

Juan Eugenio Iglesias

Bruce Fischl

Douglas Greve

Adrian V Dalca

Affiliations

Soon will be listed here.

Abstract

Mesh-based reconstruction of the cerebral cortex is a fundamental component in brain image analysis. Classical, iterative pipelines for cortical modeling are robust but often time-consuming, mostly due to expensive procedures that involve topology correction and spherical mapping. Recent attempts to address reconstruction with machine learning methods have accelerated some components in these pipelines, but these methods still require slow processing steps to enforce topological constraints that comply with known anatomical structure. In this work, we introduce a novel learning-based strategy, TopoFit, which rapidly fits a topologically-correct surface to the white-matter tissue boundary. We design a joint network, employing image and graph convolutions and an efficient symmetric distance loss, to learn to predict accurate deformations that map a template mesh to subject-specific anatomy. This technique encompasses the work of current mesh correction, fine-tuning, and inflation processes and, as a result, offers a 150× faster solution to cortical surface reconstruction compared to traditional approaches. We demonstrate that TopoFit is 1.8× more accurate than the current state-of-the-art deep-learning strategy, and it is robust to common failure modes, such as white-matter tissue hypointensities.

Citing Articles

SurfNet: Reconstruction of Cortical Surfaces via Coupled Diffeomorphic Deformations.

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Synthetic data in generalizable, learning-based neuroimaging.

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SegCSR: Weakly-Supervised Cortical Surfaces Reconstruction from Brain Ribbon Segmentations.

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Coupled Reconstruction of Cortical Surfaces by Diffeomorphic Mesh Deformation.

Zheng H, Li H, Fan Y Adv Neural Inf Process Syst. 2024; 36:80608-80621.

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NN: Joint Reconstruction of Multiple Cortical Surfaces from Magnetic Resonance Images.

Zheng H, Li H, Fan Y Proc IEEE Int Symp Biomed Imaging. 2023; 2023.

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