绘制皮肤科伤口闭合的有限元机械图谱

arXiv - QuanBio - Tissues and Organs Pub Date : 2024-06-11 DOI:arxiv-2406.06957

Congzhou M Sha

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引用次数: 0

摘要

伤口的几何形状和人体皮肤的机械特性决定了部分愈合或瘢痕组织的破坏模式。虽然皮肤科医生和外科医生通过临床实践对皮肤的机械特性有了直观的了解，但伤口的有限元模型可以帮助人们将直觉非正式化。在这项工作中，我们探索了伤口几何形状和原意闭合对机械应力在皮肤中传播的影响。我们使用表皮、真皮和皮下的双层、正交、超弹性模型来准确捕捉工作中的机械和几何效应。我们强调了在建立原发性伤口闭合模型时必须做出的关键假设，并明确指出了模型改进的前景领域。模型是在开源有限元框架 DOLFINx 中实现的，并提供了参考代码，以便进行可复制和可扩展的科学研究。

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Charting a finite element, mechanical atlas of dermatologic wound closure

Wound geometry and the mechanical properties of human skin govern the failure modes of partially healed or scarred tissue. Though dermatologists and surgeons develop an intuitive understanding of the mechanical characteristics of skin through clinical practice, finite element models of wounds can aid in formalizing intuition. In this work, we explore the effect of wound geometry and primary intention closure on the propagation of mechanical stresses through skin. We use a two-layer, orthotropic, hyperelastic model of the epidermis, dermis, and subcutis to accurately capture the mechanical and geometric effects at work. We highlight the key assumptions which must be made when modeling closure of wounds by primary intention, clearly delineating promising areas for model improvement. Models are implemented in DOLFINx, an open-source finite element framework, and reference code is provided for reproducible and extensible science.

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arXiv - QuanBio - Tissues and Organs

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