基于数学表面函数的气道支架设计与3D打印。

IF 3.2 Q1 RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING
Bengi Yilmaz, Bilge Yilmaz Kara
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引用次数: 1

摘要

背景:三维(3D)打印是一种应用于从数字模型构建任何形状的3D对象的方法,它提供了关键的优势,特别是将患者特定的设计转移到临床环境中。本研究的主要目的是介绍新设计的复杂气道支架模型,该模型通过数学函数创建并通过3D打印制造用于现实生活中的实施。方法:采用数学建模软件MathMod设计5种不同的气道支架。利用基于立体光刻技术的3D打印技术制造具有指定尺度的高多孔结构。利用扫描电子显微镜(SEM)观察了3D打印零件的微观结构细节。通过压缩试验比较了不同设计、不同孔隙度的气道支架的力学性能。结果:数学建模软件输出成功转化为3D可打印文件,3D打印气孔率大于85%的气道支架。扫描电镜图像显示了高分辨率3D打印部件的分层形貌。压缩试验表明,基于数学函数的设计提供了在不改变材料或制造方法的情况下调整气道支架机械强度的机会。结论:本研究提出了一种新的方法,包括基于数学函数的设计和3D打印技术,用于制造气道支架,作为未来治疗中央气道病变的有前途的工具。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Mathematical surface function-based design and 3D printing of airway stents.

Mathematical surface function-based design and 3D printing of airway stents.

Mathematical surface function-based design and 3D printing of airway stents.

Mathematical surface function-based design and 3D printing of airway stents.

Background: Three-dimensional (3D) printing is a method applied to build a 3D object of any shape from a digital model, and it provides crucial advantages especially for transferring patient-specific designs to clinical settings. The main purpose of this study is to introduce the newly designed complex airway stent models that are created through mathematical functions and manufactured with 3D printing for implementation in real life.

Methods: A mathematical modeling software (MathMod) was used to design five different airway stents. The highly porous structures with designated scales were fabricated by utilizing a stereolithography-based 3D printing technology. The fine details in the microstructure of 3D printed parts were observed by a scanning electron microscope (SEM). The mechanical properties of airway stents with various designs and porosity were compared by compression test.

Results: The outputs of the mathematical modeling software were successfully converted into 3D printable files and airway stents with a porosity of more than 85% were 3D printed. SEM images revealed the layered topography of high-resolution 3D printed parts. Compression tests have shown that the mathematical function-based design offers the opportunity to adjust the mechanical strength of airway stents without changing the material or manufacturing method.

Conclusions: A novel approach, which includes mathematical function-based design and 3D printing technology, is proposed in this study for the fabrication of airway stents as a promising tool for future treatments of central airway pathologies.

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