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Main Authors: Vafaeefar, Mahtab, Quinn, Conall, Vaughan, Ted J.
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2510.24752
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author Vafaeefar, Mahtab
Quinn, Conall
Vaughan, Ted J.
author_facet Vafaeefar, Mahtab
Quinn, Conall
Vaughan, Ted J.
contents In early years of life, the cranium rapidly changes in size and shape to accommodate brain growth, primarily driven by mechanical stress from brain expansion. Developmental disorders such as premature fusion of sutures in craniosynostosis, disrupts normal growth process, leading to abnormal skull shapes. Thus, understanding the interplay between biomechanical forces, soft tissues, and individual bone plates is crucial for understanding their role in shaping infant skulls. This study develops a mechanically-driven growth model to simulate healthy cranial growth in the first year. The algorithm considers simultaneous and coupled growth of brain, cranial bones, sutures, with volumetric brain expansion as the primary driver, with strain-based feedback governing growth in bone and suture tissues. A bulk bone formation approach accounts for evolving mechanical properties, with elastic moduli of bone and sutures increasing monthly. The model was applied on individual fused sutures and skull dysmorphologies due to craniosynostosis were predicted, and results showed good agreement with clinically observations. Stress at bone-suture interfaces and elevated intracranial pressure under fused sutures highlighted biomechanical impacts due to the disorders. Sensitivity analysis explored how material properties and growth rates affect skull shape. This framework enhances understanding of cranial growth and supports treatment planning for craniosynostosis.
format Preprint
id arxiv_https___arxiv_org_abs_2510_24752
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Mechanically Regulated Cranial Growth in Infancy: A Computational Approach to Predicting Craniosynostosis
Vafaeefar, Mahtab
Quinn, Conall
Vaughan, Ted J.
Tissues and Organs
Biological Physics
In early years of life, the cranium rapidly changes in size and shape to accommodate brain growth, primarily driven by mechanical stress from brain expansion. Developmental disorders such as premature fusion of sutures in craniosynostosis, disrupts normal growth process, leading to abnormal skull shapes. Thus, understanding the interplay between biomechanical forces, soft tissues, and individual bone plates is crucial for understanding their role in shaping infant skulls. This study develops a mechanically-driven growth model to simulate healthy cranial growth in the first year. The algorithm considers simultaneous and coupled growth of brain, cranial bones, sutures, with volumetric brain expansion as the primary driver, with strain-based feedback governing growth in bone and suture tissues. A bulk bone formation approach accounts for evolving mechanical properties, with elastic moduli of bone and sutures increasing monthly. The model was applied on individual fused sutures and skull dysmorphologies due to craniosynostosis were predicted, and results showed good agreement with clinically observations. Stress at bone-suture interfaces and elevated intracranial pressure under fused sutures highlighted biomechanical impacts due to the disorders. Sensitivity analysis explored how material properties and growth rates affect skull shape. This framework enhances understanding of cranial growth and supports treatment planning for craniosynostosis.
title Mechanically Regulated Cranial Growth in Infancy: A Computational Approach to Predicting Craniosynostosis
topic Tissues and Organs
Biological Physics
url https://arxiv.org/abs/2510.24752