A MULTISCALE COMPUTATIONAL MODEL FOR THE GROWTH OF THE CRANIAL VAULT IN CRANIOSYNOSTOSIS.

International Mechanical Engineering Congress and Exposition : [proceedings]. International Mechanical Engineering Congress and Exposition Pub Date : 2014-11-01 DOI:10.1115/IMECE2014-38728

Chanyoung Lee, Joan T Richtsmeier, Reuben H Kraft

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引用次数: 3

Abstract

Craniosynostosis is a condition defined by premature closure of cranial vault sutures, which is associated with abnormalities of the brain and skull. Many causal relationships between discovered mutations and premature suture closure have been proposed but an understanding of the precise mechanisms remains elusive. This article describes a computational framework of biological processes underlying cranial growth that will enable a hypothesis driven investigation of craniosynostosis phenotypes using reaction-diffusion-advection methods and the finite element method. Primary centers of ossification in cranial vault are found using activator-substrate model that represents the behavior of key molecules for bone formation. Biomechanical effects due to the interaction between growing bone and soft tissue is investigated to elucidate the mechanism of growth of cranial vault.

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颅缝闭合症颅穹窿生长的多尺度计算模型。

颅缝闭锁是一种由颅穹窿缝合线过早闭合所定义的疾病，它与大脑和颅骨的异常有关。已发现的突变和过早缝合之间的许多因果关系已被提出，但对精确机制的理解仍然难以捉摸。这篇文章描述了一个潜在颅骨生长的生物过程的计算框架，这将使假设驱动的颅缝闭合表型研究使用反应-扩散-平流方法和有限元方法。使用激活物-底物模型发现颅穹窿骨化的主要中心，该模型代表骨形成的关键分子的行为。研究了生长骨与软组织相互作用的生物力学效应，以阐明颅穹窿生长的机制。

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International Mechanical Engineering Congress and Exposition : [proceedings]. International Mechanical Engineering Congress and Exposition

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