新型 3D 打印生物活性碳化硅骨科螺钉可促进巨噬细胞、神经元和成骨细胞的骨生长相关活动。

Ahmed El-Ghannam, Farjana Sultana, Didier Dréau, Arjun Tiwari, In Hong Yang, Randa AlFotawi, Christine Knabe-Ducheyne
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引用次数: 0

摘要

陶瓷增材制造目前依赖于粘合剂或高能激光器,但每种方法都有其局限性,会影响最终产品质量和医疗应用的适用性。为了应对这些挑战,我们的实验室设计了一种陶瓷颗粒表面活化技术,在陶瓷快速成型制造中无需使用聚合物粘合剂或高能激光。我们利用这种方法三维打印了具有生物活性的碳化硅骨科螺钉,并对其性能进行了评估。研究结果表明,碳化硅的化学氧化激活了其表面,从而可以在粘合剂喷射打印机中进行骨科螺钉的三维打印。用 NaOH 和/或 NH4OH 进行后处理浸渍可促进二氧化硅结晶或将氧化硅部分转化为氮化硅,从而强化支架。碳化硅三维打印骨科螺钉的二氧化硅表面有利于成骨细胞和神经元的粘附以及大量轴突的合成。三维打印碳化硅螺钉释放出的硅酸根离子可抑制 TNFα 的分泌和活性氧(ROS)的表达,并促进 IL6R 的脱落,从而有利地调节巨噬细胞的免疫反应,使其向 M1 表型发展。相反,在相同的实验条件下,Ti6Al4V 盘释放的钛离子促进了巨噬细胞 TNFα 的分泌和 ROS 的表达。体内测试表明,骨直接沉积在碳化硅支架上,植入的碳化硅和骨之间有很强的界面结合力。免疫染色显示,在与碳化硅的界面上,新形成的骨有神经支配、矿化和血管化。总而言之,三维打印碳化硅骨科螺钉为伤口愈合和骨再生创造了有利环境。基于陶瓷表面活化的新型三维打印方法代表了陶瓷添加剂制造领域的一大进步,适用于多种材料。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Novel 3D printed bioactive SiC orthopedic screw promotes bone growth associated activities by macrophages, neurons, and osteoblasts.

Ceramic additive manufacturing currently relies on binders or high-energy lasers, each with limitations affecting final product quality and suitability for medical applications. To address these challenges, our laboratory has devised a surface activation technique for ceramic particles that eliminates the necessity for polymer binders or high-energy lasers in ceramic additive manufacturing. We utilized this method to 3D print bioactive SiC orthopedic screws and evaluated their properties. The study's findings reveal that chemical oxidation of SiC activated its surface, enabling 3D printing of orthopedic screws in a binder jet printer. Post-processing impregnation with NaOH and/or NH4OH strengthened the scaffold by promoting silica crystallization or partial conversion of silicon oxide into silicon nitride. The silica surface of the SiC 3D printed orthopedic screws facilitated osteoblast and neuron adhesion and extensive axon synthesis. The silicate ions released from the 3D printed SiC screws favorably modulated macrophage immune responses toward an M1 phenotype as indicated by the inhibition of TNFα secretions and of reactive oxygen species (ROS) expression along with the promotion of IL6R shedding. In contrast, under the same experimental conditions, Ti ions released from Ti6Al4V discs promoted macrophage TNFα secretion and ROS expression. In vivo tests demonstrated direct bone deposition on the SiC scaffold and a strong interfacial bond between the implanted SiC and bone. Immunostaining showed innervation, mineralization, and vascularization of the newly formed bone at the interface with SiC. Taken altogether, the 3D printed SiC orthopedic screws foster a favorable environment for wound healing and bone regeneration. The novel 3D printing method, based on ceramic surface activation represents a significant advancement in ceramic additive manufacturing and is applicable to a wide variety of materials.

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