Computational modelling of bone growth and mineralization surrounding biodegradable Mg-based and permanent Ti implants

arXiv - QuanBio - Tissues and Organs Pub Date : 2024-08-07 DOI:arxiv-2408.03820

Domenik Priebe, Nik Pohl, Tamadur AlBaraghtheh, Sven Schimek, Florian Wieland, Diana Krüger, Sascha Trostorff, Regine Willumeit-Römer, Ralf Köhl, Berit Zeller-Plumhoff

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Abstract

In silico testing of implant materials is a research area of high interest, as cost- and labour-intensive experiments may be omitted. However, assessing the tissue-material interaction mathematically and computationally can be very complex, in particular when functional, such as biodegradable, implant materials are investigated. In this work, we expand and refine suitable existing mathematical models of bone growth and magnesium-based implant degradation based on ordinary differential equations. We show that we can simulate the implant degradation, as well as the osseointegration in terms of relative bone volume fraction and changes in bone ultrastructure when applying the model to experimental data from titanium and magnesium-gadolinium implants for healing times up to 32 weeks. By conducting a parameter study we further show that a lack of data at early time points has little influence on the simulation outcome. Moreover, we show that the model is predictive in terms of relative bone volume fraction with mean absolute errors below 6%

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生物可降解镁基和永久性钛植入物周围骨生长和矿化的计算建模

植入材料的硅学测试是一个备受关注的研究领域，因为可以省去成本和人力密集型实验。然而，用数学和计算方法评估组织与材料之间的相互作用可能非常复杂，尤其是在研究生物可降解等功能性植入材料时。在这项研究中，我们以常微分方程为基础，扩展并完善了现有的骨生长和镁基植入体降解数学模型。我们的研究表明，将该模型应用于钛和镁-钆种植体愈合时间长达 32 周的实验数据时，我们可以从骨体积分数和骨超微结构变化的角度模拟种植体降解和骨结合。通过进行参数研究，我们进一步证明，早期时间点数据的缺乏对模拟结果的影响很小。此外，我们还证明了该模型对相对骨体积分数的预测能力，其平均绝对误差低于 6% 。

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arXiv - QuanBio - Tissues and Organs

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