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CIR | Fetal development

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We are studying fetal brain development based on in-utero magnetic resonance imaging data  acquired from the 18th to 40th gestational week, with a focus on modelling structural- and functional changes during gestation.

Projects

Ongoing: FASD, TRABITFinished: FETAL4D, FETALMORPHO, FETLAS

Workshops, Challenges and Awards

The prenatal assessment of functional asymmetries in the developing human brain using in-utero fMRI, presented at FIT'NG 2022 on 5th of September 2022 by Athena Taymourtash received the FIT'NG Young Investigator Award!

We are Co-organisers of the FeTal brain Annotation and Segmentation (FeTA) Challenge since 2021. New this year: Multi-site generalization segmentation task with also data from the Medical University of Vienna! Check out the  hybrid presentations on 18th of September during MICCAI 2022.

 

Highlight Publications

NEW PAPER: Fetal brain morphology as a predictor for language development. This study investigated the prognostic value of STS depth asymmetry in healthy fetuses for later language abilities, language localization, and language-related white matter tracts. Less right lateralization of the fetal STS depth was significantly associated with better verbal abilities, with fetal STS depth asymmetry explaining more than 40% of variance in verbal skills 6–13 years later. Furthermore, less right fetal STS depth asymmetry correlated with increased left language localization during childhood.  (Lisa Bartha-Doering et al. Communications Biology 2023)   

Fetal functional thalamo-cortical and cortico-cortical networks develop along specific trajectories. We modeled fetal functional thalamocortical connectome development using in-utero functional MRI in fetuses observed from 19th to 40th weeks of gestation. A peak increase of thalamo-cortical functional connectivity strength occurs between 29th and 31st GW, right before axons establish synapses in the cortex. The cortico-cortical connectivity increases in a similar time window, and exhibits significant functional laterality in temporal-superior, -medial, and -inferior areas. The similarity of homologous regions decreases during gestation giving way to a more diverse cortical interconnectedness.  (Taymourtash et al. 2022 Cerebral Cortex)

Motion correction and volumetric reconstruction for fetal functional magnetic resonance imaging data estimates a high-resolution reference volume by using outlier-robust motion correction, and utilizes Huber L2 regularization for intra-stack volumetric reconstruction of the motion-corrected fetal brain fMRI. (Sobotka et al. 2022 Neuroimage)

Spatio-temporal motion correction using iterative reconstruction of in-utero fetal fMRI. 4D low-rank regularization can reconstruct the entire time series at once and exploits relationships within, and across time frames (Taymourtash et al. 2022 MICCAI)

Fetal functional brain networks emerge during gestation following a stabled timing. Region-specific increase of functional signal synchrony followed a sequence of occipital (peak: 24.8 GW), temporal (peak: 26 GW), frontal (peak: 26.4 GW), and parietal expansion (peak: 27.5 GW). (Jakab et al. 2014)

The organization of structural connectivity an ts development in the fetal brain is discrupted by disease. Corpus callosum agenesis effects specific changes not only in the inter-hemispheric connections, but also within hemispheres. Each follows a characteristic timing. (Jakab et al. 2015)

Cortical expansion during fetal development can be modelled by comparing cortical surfaces across many individuals and linking their shape to gestaional age. We developed regularlization approaches that facilitate reliable estimates of development models. (Schwartz et al. 2016).

Development of the brain parenchymum proceeds in successive migrational waves of neuronal migration. The resulting laminar intensity profiles observable in both histology and in utero are indicative of developmental processes and important markers for neurodevelopmental diseases. We showed that the time-course of shifting patterns of laminar cortical structure can be modeled from fetal MRI.

Publications

Images: MUW/Bartha-Doering, MUW/Taymourtash, MUW/Sobotka, MUW/Jakab,