Frontiers in Neuroscience (Dec 2023)

Characterization of dynamic patterns of human fetal to neonatal brain asymmetry with deformation-based morphometry

  • Céline Steger,
  • Céline Steger,
  • Céline Steger,
  • Céline Steger,
  • Charles Moatti,
  • Charles Moatti,
  • Kelly Payette,
  • Kelly Payette,
  • Alexandra De Silvestro,
  • Alexandra De Silvestro,
  • Alexandra De Silvestro,
  • Thi Dao Nguyen,
  • Seline Coraj,
  • Ninib Yakoub,
  • Giancarlo Natalucci,
  • Giancarlo Natalucci,
  • Raimund Kottke,
  • Ruth Tuura,
  • Ruth Tuura,
  • Walter Knirsch,
  • Walter Knirsch,
  • Andras Jakab,
  • Andras Jakab,
  • Andras Jakab

DOI
https://doi.org/10.3389/fnins.2023.1252850
Journal volume & issue
Vol. 17

Abstract

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IntroductionDespite established knowledge on the morphological and functional asymmetries in the human brain, the understanding of how brain asymmetry patterns change during late fetal to neonatal life remains incomplete. The goal of this study was to characterize the dynamic patterns of inter-hemispheric brain asymmetry over this critically important developmental stage using longitudinally acquired MRI scans.MethodsSuper-resolution reconstructed T2-weighted MRI of 20 neurotypically developing participants were used, and for each participant fetal and neonatal MRI was acquired. To quantify brain morphological changes, deformation-based morphometry (DBM) on the longitudinal MRI scans was utilized. Two registration frameworks were evaluated and used in our study: (A) fetal to neonatal image registration and (B) registration through a mid-time template. Developmental changes of cerebral asymmetry were characterized as (A) the inter-hemispheric differences of the Jacobian determinant (JD) of fetal to neonatal morphometry change and the (B) time-dependent change of the JD capturing left-right differences at fetal or neonatal time points. Left-right and fetal-neonatal differences were statistically tested using multivariate linear models, corrected for participants’ age and sex and using threshold-free cluster enhancement.ResultsFetal to neonatal morphometry changes demonstrated asymmetry in the temporal pole, and left-right asymmetry differences between fetal and neonatal timepoints revealed temporal changes in the temporal pole, likely to go from right dominant in fetal to a bilateral morphology in neonatal timepoint. Furthermore, the analysis revealed right-dominant subcortical gray matter in neonates and three clusters of increased JD values in the left hemisphere from fetal to neonatal timepoints.DiscussionWhile these findings provide evidence that morphological asymmetry gradually emerges during development, discrepancies between registration frameworks require careful considerations when using DBM for longitudinal data of early brain development.

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