Allometry of human calvaria bones during development from birth to 8 years of age shows a nonlinear growth pattern

Pediatric skulls change rapidly in size and shape during development, especially for children up to 8 years of age. This project was developed to address the gap in understanding of the three-dimensional growth parameters of the human skull during this period and the impact these growth patterns hav...

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Veröffentlicht in:Scientific reports 2024-10, Vol.14 (1), p.26205-15, Article 26205
Hauptverfasser: Schaurich, Cristina Goes, Saraco, Anthony N., Oruganti, Maanas Hemanth, Tamber, Mandeep S., Haetinger, Rainer Guilherme, Dixit, Ishan, Lo, Bailey S. Y., Krebs, Claudia, Steinbok, Paul
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Sprache:eng
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Zusammenfassung:Pediatric skulls change rapidly in size and shape during development, especially for children up to 8 years of age. This project was developed to address the gap in understanding of the three-dimensional growth parameters of the human skull during this period and the impact these growth patterns have on fontanelle closure and suture formation. This study offers novel data on the dynamic changes in the anatomy of the skull with the intention of providing better guidance for pediatric surgical care. Craniometric landmarks defined on three-dimensional computed tomography reconstructions were used to map skull development in children aged 0 to 8 years old. A total of 364 datasets were analyzed and statistically representative 3D skulls with anatomical craniometric features such as head shape, bone size, suture and fontanelle closure time were generated for 17 age groups spanning birth to 8 years of age to provide a comprehensive neuroanatomical understanding of how the pediatric skull changes over time. This study indicates that the cranial bones follow a non-linear growth pattern, with the occipital and frontal bones driving the directionality of fontanelle closure and delivers a 3D visualization of the developmental characteristics of the skull providing a landmark resource for understanding the growth dynamics of the human skull. While clinical measurements remain valid approaches for the planning of surgical interventions, these 3D models may provide a more accurate planning paradigm.
ISSN:2045-2322
2045-2322
DOI:10.1038/s41598-024-77315-8