W Qin, M H Shen, N Gan, B H Xing, J Sun, Z Zhao, T Jiao
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引用次数: 0
摘要
有关三维(3D)打印多孔氧化锆牙科植入物的研究仍处于起步阶段。本研究旨在评估通过三维打印技术制造的具有多孔结构的新型氧化锆种植体的生物反应。与之前用传统方法制备的样本相比,固体氧化锆样本表现出相当的密度、三点抗弯强度和加速老化性能。基于细胞的实验表明,p-细胞结构促进了细胞增殖、粘附和成骨相关蛋白的表达。机械测试表明,p-细胞和对照组植入物都能承受 35 Ncm 的扭矩而不断裂。p-cell 种植体和对照组种植体的平均最大断裂载荷分别为 1,222.429 ± 115.591 N 和 1,903.857 ± 250.673 N,远高于人体生理咀嚼力和人体平均最大咬合力。动物实验表明,p-细胞组种植体周围的骨小梁明显比对照组厚、多、密。这项研究为进一步探索牙科中多孔氧化锆仿生种植体的 3D 打印技术提供了很好的指导。
Biological Properties of 3D-Printed Zirconia Implants with p-Cell Structures.
Research on 3-dimensional (3D) printed porous zirconia-based dental implants is still in its infancy. This study aimed to evaluate the biological responses of novel zirconia implants with p-cell structures fabricated by 3D printing. The solid zirconia samples exhibited comparable density, 3-point flexural strength, and accelerated aging properties compared to specimens prepared previously by conventional methods. Cell-based experiments showed that the p-cell structure promoted cell proliferation, adhesion, and osteogenesis-related protein expression. Mechanical tests showed that both p-cell and control implants could withstand a torque of 35 Ncm without breaking. The mean maximum breaking loads of p-cell and control implants were 1,222.429 ± 115.591 N and 1,903.857 ± 250.673 N, respectively, which were much higher than the human physiological chewing force and human mean maximum occlusal force. An animal experiment showed that the bone trabeculae around the implants were significantly thicker, more numerous, and denser in the p-cell group than in the control group. This work could provide promising guidance for further exploring 3D printing techniques for porous zirconia bionic implants in dentistry.
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