生物启发的耐损伤磷酸钙大块材料的开发。

IF 7.4 3区 材料科学 Q1 MATERIALS SCIENCE, MULTIDISCIPLINARY
Science and Technology of Advanced Materials Pub Date : 2023-10-12 eCollection Date: 2023-01-01 DOI:10.1080/14686996.2023.2261836
Karen Kuroyama, Ryuichi Fujikawa, Tomoyo Goto, Tohru Sekino, Fumiya Nakamura, Hiromi Kimura-Suda, Peng Chen, Hiroyasu Kanetaka, Tomoka Hasegawa, Kaname Yoshida, Masaru Murata, Hidemi Nakata, Masaya Shimabukuro, Masakazu Kawashita, Tetsuya Yoda, Taishi Yokoi
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引用次数: 0

摘要

提高陶瓷人工骨材料的损伤容限和可靠性至关重要,例如羟基磷灰石烧结体(HAp),这些材料在体内长时间保留。然而,陶瓷固有的脆性和低损伤容限使这一点具有挑战性。本文报道了一种基于生物启发设计的新型人造骨的高耐损伤磷酸钙基材料的合成。含间苯二甲酸根离子的磷酸八钙压块在1000°C氮气氛中热处理24小时 h制备了具有砖和砂浆结构的HAp/β-磷酸三钙/热解碳复合材料(类似于珍珠层)。这种复合材料表现出优异的损伤容限,钉扎时没有脆性断裂,这可能是由于其独特的微观结构所产生的特定机械性能。其最大弯曲应力、最大弯曲应变、杨氏模量和维氏硬度分别为11.7MPa、2.8 × 分别为10-2、5.3 GPa和11.7 kgf/mm2。该材料表现出比HAp烧结体和由纯磷酸八钙压块制备的烧结体样品更低的杨氏模量和更高的断裂应变。此外,使用模拟体液在体外证实了所获得的材料的磷灰石形成能力。所提出的仿生材料设计可以制造出在体内长时间保持的高度耐损伤的人造骨。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Development of bioinspired damage-tolerant calcium phosphate bulk materials.

Development of bioinspired damage-tolerant calcium phosphate bulk materials.

Development of bioinspired damage-tolerant calcium phosphate bulk materials.

Development of bioinspired damage-tolerant calcium phosphate bulk materials.

Improving the damage tolerance and reliability of ceramic artificial bone materials, such as sintered bodies of hydroxyapatite (HAp), that remain in vivo for long periods of time is of utmost importance. However, the intrinsic brittleness and low damage tolerance of ceramics make this challenging. This paper reports the synthesis of highly damage tolerant calcium phosphate-based materials with a bioinspired design for novel artificial bones. The heat treatment of isophthalate ion-containing octacalcium phosphate compacts in a nitrogen atmosphere at 1000°C for 24 h produced an HAp/β-tricalcium phosphate/pyrolytic carbon composite with a brick-and-mortar structure (similar to that of the nacreous layer). This composite exhibited excellent damage tolerance, with no brittle fracture upon nailing, likely attributable to the specific mechanical properties derived from its unique microstructure. Its maximum bending stress, maximum bending strain, Young's modulus, and Vickers hardness were 11.7 MPa, 2.8 × 102, 5.3 GPa, and 11.7 kgf/mm2, respectively. The material exhibited a lower Young's modulus and higher fracture strain than that of HAp-sintered bodies and sintered-body samples prepared from pure octacalcium phosphate compacts. Additionally, the apatite-forming ability of the obtained material was confirmed in vitro, using a simulated body fluid. The proposed bioinspired material design could enable the fabrication of highly damage tolerant artificial bones that remain in vivo for long durations of time.

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来源期刊
Science and Technology of Advanced Materials
Science and Technology of Advanced Materials 工程技术-材料科学:综合
CiteScore
10.60
自引率
3.60%
发文量
52
审稿时长
4.8 months
期刊介绍: Science and Technology of Advanced Materials (STAM) is a leading open access, international journal for outstanding research articles across all aspects of materials science. Our audience is the international community across the disciplines of materials science, physics, chemistry, biology as well as engineering. The journal covers a broad spectrum of topics including functional and structural materials, synthesis and processing, theoretical analyses, characterization and properties of materials. Emphasis is placed on the interdisciplinary nature of materials science and issues at the forefront of the field, such as energy and environmental issues, as well as medical and bioengineering applications. Of particular interest are research papers on the following topics: Materials informatics and materials genomics Materials for 3D printing and additive manufacturing Nanostructured/nanoscale materials and nanodevices Bio-inspired, biomedical, and biological materials; nanomedicine, and novel technologies for clinical and medical applications Materials for energy and environment, next-generation photovoltaics, and green technologies Advanced structural materials, materials for extreme conditions.
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