An energy-based technique for the development of a mechanobiological growth model of vertebrae

International journal of experimental and computational biomechanics Pub Date : 2011-05-09 DOI:10.1504/IJECB.2011.039949

Hui Lin, Mei‐qing Wang

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Abstract

Mechanobiological growth is the biological process whereby bone growth is modulated by mechanical loading. The goal of this study is to develop an energy-based mechanobiological bone growth model. Mechanobiological procedures basically include mechanosensing and mechanoregulation. This study represented the mechanosensing as a mathematical model combining energy and mechanical-triggered deformation. The mechanoregulation was modelled as a mathematical form integrated distortion and dilatation energy. Mechanobiological growth model was developed from those two procedures and represented as a function of distortion and dilatation stresses. The model was tested by using finite element model of a thoracic vertebra (T7) for simulating one-year growth procedure under multi-axial loads. The simulation results presented the retarded and stimulated growth under compression and tension. Shear stress increased the growth rate with 20%–40%. This model agreed with experimental study of growth and published numerical growth simulation of human vertebrae as well as mechanobiology theory. This model allows simulating vertebral growth under multi-direction loads.

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一种基于能量的技术，用于开发椎骨的机械生物学生长模型

机械生物学生长是骨生长受机械负荷调节的生物过程。本研究的目的是建立一种基于能量的机械生物学骨生长模型。机械生物学程序基本上包括机械传感和机械调节。本研究将机械传感描述为能量与机械触发变形相结合的数学模型。将力学调节建模为综合变形能和膨胀能的数学形式。力学生物学生长模型是由这两个过程发展起来的，并表示为扭曲和扩张应力的函数。采用胸椎(T7)有限元模型模拟多轴载荷下一年的生长过程，对模型进行了验证。模拟结果表明，在压缩和拉伸作用下，材料的生长受到了抑制和刺激。剪切应力使生长速率提高了20% ~ 40%。该模型与生长的实验研究和发表的人类椎骨的数值生长模拟以及力学生物学理论一致。该模型可以模拟椎骨在多向载荷下的生长。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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International journal of experimental and computational biomechanics

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