Related papers: Detailed delineation of the fetal brain in diffusion MRI via multi-task learning

Detailed delineation of the fetal brain in diffusion MRI via multi-task learning

URL: http://arxiv.org/abs/2409.06716v2
Date: Thu, 12 Sep 2024 12:08:20 GMT
Title: Detailed delineation of the fetal brain in diffusion MRI via multi-task learning
Authors: Davood Karimi, Camilo Calixto, Haykel Snoussi, Maria Camila Cortes-Albornoz, Clemente Velasco-Annis, Caitlin Rollins, Camilo Jaimes, Ali Gholipour, Simon K. Warfield,
Abstract summary: We developed and validated a unified computational framework to segment the brain tissue into white matter, cortical/subcortical gray matter, and cerebrospinal fluid. Using these labels, we developed and validated a multi-task deep learning method to perform the three computations.
Score: 5.261252388770444
License: http://creativecommons.org/licenses/by-nc-nd/4.0/
Abstract: Diffusion-weighted MRI is increasingly used to study the normal and abnormal development of fetal brain in-utero. Recent studies have shown that dMRI can offer invaluable insights into the neurodevelopmental processes in the fetal stage. However, because of the low data quality and rapid brain development, reliable analysis of fetal dMRI data requires dedicated computational methods that are currently unavailable. The lack of automated methods for fast, accurate, and reproducible data analysis has seriously limited our ability to tap the potential of fetal brain dMRI for medical and scientific applications. In this work, we developed and validated a unified computational framework to (1) segment the brain tissue into white matter, cortical/subcortical gray matter, and cerebrospinal fluid, (2) segment 31 distinct white matter tracts, and (3) parcellate the brain's cortex and delineate the deep gray nuclei and white matter structures into 96 anatomically meaningful regions. We utilized a set of manual, semi-automatic, and automatic approaches to annotate 97 fetal brains. Using these labels, we developed and validated a multi-task deep learning method to perform the three computations. Our evaluations show that the new method can accurately carry out all three tasks, achieving a mean Dice similarity coefficient of 0.865 on tissue segmentation, 0.825 on white matter tract segmentation, and 0.819 on parcellation. The proposed method can greatly advance the field of fetal neuroimaging as it can lead to substantial improvements in fetal brain tractography, tract-specific analysis, and structural connectivity assessment.

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