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Hauptverfasser: Bastiaansen, Wietske A. P., Rousian, Melek, Koning, Anton H. J., Niessen, Wiro J., de Bakker, Bernadette S., Steegers-Theunissen, Régine P. M., Klein, Stefan
Format: Preprint
Veröffentlicht: 2025
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Online-Zugang:https://arxiv.org/abs/2503.07177
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author Bastiaansen, Wietske A. P.
Rousian, Melek
Koning, Anton H. J.
Niessen, Wiro J.
de Bakker, Bernadette S.
Steegers-Theunissen, Régine P. M.
Klein, Stefan
author_facet Bastiaansen, Wietske A. P.
Rousian, Melek
Koning, Anton H. J.
Niessen, Wiro J.
de Bakker, Bernadette S.
Steegers-Theunissen, Régine P. M.
Klein, Stefan
contents Early brain development is crucial for lifelong neurodevelopmental health. However, current clinical practice offers limited knowledge of normal embryonic brain anatomy on ultrasound, despite the brain undergoing rapid changes within the time-span of days. To provide detailed insights into normal brain development and identify deviations, we created the 4D Human Embryonic Brain Atlas using a deep learning-based approach for groupwise registration and spatiotemporal atlas generation. Our method introduced a time-dependent initial atlas and penalized deviations from it, ensuring age-specific anatomy was maintained throughout rapid development. The atlas was generated and validated using 831 3D ultrasound images from 402 subjects in the Rotterdam Periconceptional Cohort, acquired between gestational weeks 8 and 12. We evaluated the effectiveness of our approach with an ablation study, which demonstrated that incorporating a time-dependent initial atlas and penalization produced anatomically accurate results. In contrast, omitting these adaptations led to anatomically incorrect atlas. Visual comparisons with an existing ex-vivo embryo atlas further confirmed the anatomical accuracy of our atlas. In conclusion, the proposed method successfully captures the rapid anotomical development of the embryonic brain. The resulting 4D Human Embryonic Brain Atlas provides a unique insights into this crucial early life period and holds the potential for improving the detection, prevention, and treatment of prenatal neurodevelopmental disorders.
format Preprint
id arxiv_https___arxiv_org_abs_2503_07177
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle The 4D Human Embryonic Brain Atlas: spatiotemporal atlas generation for rapid anatomical changes
Bastiaansen, Wietske A. P.
Rousian, Melek
Koning, Anton H. J.
Niessen, Wiro J.
de Bakker, Bernadette S.
Steegers-Theunissen, Régine P. M.
Klein, Stefan
Image and Video Processing
Computer Vision and Pattern Recognition
Quantitative Methods
Early brain development is crucial for lifelong neurodevelopmental health. However, current clinical practice offers limited knowledge of normal embryonic brain anatomy on ultrasound, despite the brain undergoing rapid changes within the time-span of days. To provide detailed insights into normal brain development and identify deviations, we created the 4D Human Embryonic Brain Atlas using a deep learning-based approach for groupwise registration and spatiotemporal atlas generation. Our method introduced a time-dependent initial atlas and penalized deviations from it, ensuring age-specific anatomy was maintained throughout rapid development. The atlas was generated and validated using 831 3D ultrasound images from 402 subjects in the Rotterdam Periconceptional Cohort, acquired between gestational weeks 8 and 12. We evaluated the effectiveness of our approach with an ablation study, which demonstrated that incorporating a time-dependent initial atlas and penalization produced anatomically accurate results. In contrast, omitting these adaptations led to anatomically incorrect atlas. Visual comparisons with an existing ex-vivo embryo atlas further confirmed the anatomical accuracy of our atlas. In conclusion, the proposed method successfully captures the rapid anotomical development of the embryonic brain. The resulting 4D Human Embryonic Brain Atlas provides a unique insights into this crucial early life period and holds the potential for improving the detection, prevention, and treatment of prenatal neurodevelopmental disorders.
title The 4D Human Embryonic Brain Atlas: spatiotemporal atlas generation for rapid anatomical changes
topic Image and Video Processing
Computer Vision and Pattern Recognition
Quantitative Methods
url https://arxiv.org/abs/2503.07177