Bio-inspired 3D printing of layered structures utilizing stabilized amorphous calcium carbonate within biodegradable matrices†

IF 5.2 Q2 MATERIALS SCIENCE, MULTIDISCIPLINARY
Hadar Shaked, Daniela Dobrynin, Iryna Polishchuk, Alexander Katsman and Boaz Pokroy
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Abstract

Many composites in nature are formed in the course of biomineralization. These biocomposites are often produced via an amorphous precursor such as amorphous calcium carbonate (ACC), demonstrating a layered structure. In the current study, robocasting, a 3D-printing technique, was used to print layered structures inspired by the mineralized tissues of Ophiomastix wendtii and Odontodactylus scyllarus, which exhibit a layered organization. Various biodegradable organic matrices with a high percentage (>94%) of ACC reinforcements were compared, and their mechanical properties were studied. With the organic matrix protection, ACC was stabilized for long periods, exceeding even three years, when stored at ambient conditions. The layered structures were printed and fractured using the three-point bending method to evaluate their strength. The fracture interface was examined to weigh the benefits an amorphous precursor may offer in the 3D printing processes of ceramic materials. The fracture interface presented bulk behavior with no distinct layering, resembling the formation of mineral single crystalline tissue in nature and overcoming one of the most critical challenges in 3D printing, namely the inter-layer interfaces. Herein, a bio-inspired, low-temperature route to form layered structures is presented. By fusing the layers together following low-temperature sintering, a composite structure composed of stabilized ACC integrated with biodegradable, environmentally friendly matrices can be obtained.

Abstract Image

利用生物可降解基质中的稳定无定形碳酸钙进行分层结构的生物启发 3D 打印†。
自然界中的许多复合材料都是在生物矿化过程中形成的。这些生物复合材料通常是通过无定形前体(如无定形碳酸钙(ACC))产生的,并呈现出分层结构。在当前的研究中,受 Ophiomastix wendtii 和 Odontodactylus scyllarus 矿化组织的启发,使用了机器人铸造这种三维打印技术来打印分层结构。我们比较了含有高比例(94%)ACC 增强材料的各种可生物降解有机基质,并研究了它们的机械性能。在有机基质的保护下,ACC 在环境条件下可长期稳定保存,甚至超过三年。对分层结构进行了打印,并使用三点弯曲法对其进行断裂,以评估其强度。对断裂界面进行了检查,以权衡无定形前驱体在陶瓷材料 3D 打印过程中可能带来的益处。断裂界面呈现出没有明显分层的块状行为,类似于自然界中矿物单晶组织的形成,克服了三维打印中最关键的挑战之一,即层间界面。本文介绍了一种受生物启发的低温形成分层结构的方法。通过在低温烧结后将各层融合在一起,可获得由稳定的 ACC 与可生物降解的环保基质组成的复合结构。
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来源期刊
Materials Advances
Materials Advances MATERIALS SCIENCE, MULTIDISCIPLINARY-
CiteScore
7.60
自引率
2.00%
发文量
665
审稿时长
5 weeks
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