Large-pore-size Ti6Al4V scaffolds with different pore structures for vascularized bone regeneration

IF 8.1 1区 工程技术 Q1 MATERIALS SCIENCE, BIOMATERIALS
Chao Wang , Duoling Xu , Ling Lin , Shujun Li , Wentao Hou , Yi He , Liyuan Sheng , Chen Yi , Xiliu Zhang , Hongyu Li , Yiming Li , Wei Zhao , Dongsheng Yu
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引用次数: 34

Abstract

Porous Ti6Al4V scaffolds are characterized by high porosity, low elastic modulus, and good osteogenesis and vascularization, which are expected to facilitate the repair of large-scale bone defects in future clinical applications. Ti6Al4V scaffolds are divided into regular and irregular structures according to the pore structure, but the pore structure more capable of promoting bone regeneration and angiogenesis has not yet been reported. The purpose of this study was to explore the optimal pore structure and pore size of the Ti6Al4V porous scaffold for the repair of large-area bone defects and the promotion of vascularization in the early stage of osteogenesis. 7 groups of porous Ti6Al4V scaffolds, named NP, R8, R9, R10, P8, P9 and P10, were fabricated by Electron-beam-melting (EBM). Live/dead staining, immunofluorescence staining, SEM, CCK8, ALP, and PCR were used to detect the adhesion, proliferation, and differentiation of BMSCs on different groups of scaffolds. Hematoxylin-eosin (HE) staining and Van Gieson (VG) staining were used to detect bone regeneration and angiogenesis in vivo. The research results showed that as the pore size of the scaffold increased, the surface area and volume of the scaffold gradually decreased, and cell proliferation ability and cell viability gradually increased. The ability of cells to vascularize on scaffolds with irregular pore sizes was stronger than that on scaffolds with regular pore sizes. Micro-CT 3D reconstruction images showed that bone regeneration was obvious and new blood vessels were thick on the P10 scaffold. HE and VG staining showed that the proportion of bone area on the scaffolds with irregular pores was higher than that on scaffolds with regular pores. P10 had better mechanical properties and were more conducive to bone tissue ingrowth and blood vessel formation, thereby facilitating the repair of large-area bone defects.

不同孔隙结构大孔径Ti6Al4V支架血管化骨再生研究
多孔Ti6Al4V支架具有孔隙率高、弹性模量低、成骨血管化良好等特点,有望在未来的临床应用中促进大规模骨缺损的修复。Ti6Al4V支架根据孔隙结构分为规则结构和不规则结构,但更能促进骨再生和血管生成的孔隙结构尚未见报道。本研究的目的是探索Ti6Al4V多孔支架修复大面积骨缺损和促进成骨早期血管化的最佳孔隙结构和孔径。采用电子束熔融法制备了7组多孔Ti6Al4V支架,分别命名为NP、R8、R9、R10、P8、P9和P10。采用活/死染色、免疫荧光染色、SEM、CCK8、ALP、PCR检测骨髓间充质干细胞在不同组支架上的粘附、增殖和分化情况。苏木精-伊红(HE)染色和Van Gieson (VG)染色检测骨再生和血管生成。研究结果表明,随着支架孔径的增大,支架的表面积和体积逐渐减小,细胞增殖能力和细胞活力逐渐提高。细胞在不规则孔径支架上血管化的能力比在规则孔径支架上更强。显微ct三维重建图像显示,P10支架骨再生明显,新生血管粗大。HE和VG染色显示,不规则孔隙支架的骨面积比例高于规则孔隙支架。P10具有更好的力学性能,更有利于骨组织长入和血管形成,有利于大面积骨缺损的修复。
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来源期刊
CiteScore
12.60
自引率
0.00%
发文量
28
审稿时长
3.3 months
期刊介绍: Materials Today is a community committed to fostering the creation and sharing of knowledge and experience in materials science. With the support of Elsevier, this community publishes high-impact peer-reviewed journals, organizes academic conferences, and conducts educational webinars, among other initiatives. It serves as a hub for advancing materials science and facilitating collaboration within the scientific community.
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