Mechanical characterization of miniaturized 3D-printed hydroxyapatite parts obtained through vat photopolymerization: an experimental study.

L. D’andrea, D. Gastaldi, F. Baino, E. Verné, G. Saccomano, L. D’Amico, E. Longo, M. Schwentenwein, P. Vena
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引用次数: 3

Abstract

Hydroxyapatite is one of the materials of choice for tissue engineering bone scaffolds manufacturing. Vat photopolymerization (VPP) is a promising Additive Manufacturing (AM) technology capable of producing scaffolds with high resolution micro-architecture and complex shapes. However, mechanical reliability of ceramic scaffolds can be achieved if a high fidelity printing process is obtained and if knowledge of the intrinsic mechanical properties of the constituent material is available. As the hydroxyapatite (HAP) obtained from VPP is subjected to a sintering process, the mechanical properties of the material should be assessed with specific reference to the process parameters (e.g. sintering temperature) and to the specific characteristic size of the microscopic features in the scaffolds. In order to tackle this challenge the HAP solid matrix of the scaffold was mimicked in the form of miniaturized samples suitable for ad hoc mechanical characterization, which is an unprecedented approach. To this purpose small scale HAP samples, having a simple geometry and size similar to that of the scaffolds, were produced through VPP. The samples were subjected to geometric characterization and to mechanical laboratory tests. Confocal laser scanning and Computed micro-Tomography (micro-CT) were used for geometric characterization; while, micro-bending and nanoindentation were used for mechanical testing. Micro-CT analyses have shown a highly dense material with negligible intrinsic micro-porosity. The imaging process allowed quantifying the variation of geometry with respect to the nominal size showing high accuracy of the printing process and identifying printing defects on one specific sample type, depending on the printing direction. The mechanical tests have shown that the VPP produces HAP with an elastic modulus as high as approximately 100GPa and flexural strength of approximately 100MPa. The results of this study have shown that vat photopolymerization is a promising technology capable of producing high quality HAP with reliable geometric fidelity.
通过还原光聚合获得的小型化3D打印羟基磷灰石零件的机械表征:一项实验研究。
羟基磷灰石是制备组织工程骨支架的首选材料之一。还原光聚合(VPP)是一种很有前途的增材制造(AM)技术,能够生产具有高分辨率微结构和复杂形状的支架。然而,如果获得了高保真的打印工艺,并且了解了组成材料的内在机械性能,陶瓷支架的机械可靠性是可以实现的。由于从VPP中获得的羟基磷灰石(HAP)经过烧结工艺,因此材料的力学性能应具体参考工艺参数(例如烧结温度)和支架中微观特征的特定特征尺寸来评估。为了解决这一挑战,支架的HAP固体基质以适合特殊力学表征的小型化样品的形式进行模拟,这是一种前所未有的方法。为此,通过VPP法制备了具有简单几何形状和尺寸与支架相似的小规模HAP样品。样品进行了几何表征和机械实验室测试。利用激光共聚焦扫描和计算机微断层扫描(micro-CT)进行几何表征;采用微弯曲和纳米压痕进行力学测试。显微ct分析显示,高密度材料具有可忽略不计的固有微孔隙率。成像过程可以量化相对于标称尺寸的几何变化,显示印刷过程的高精度,并根据印刷方向确定特定样品类型的印刷缺陷。力学试验表明,VPP制备的HAP弹性模量高达约100GPa,抗弯强度约100MPa。本研究结果表明,还原光聚合是一种有前途的技术,能够生产高质量的HAP,具有可靠的几何保真度。
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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