用于骨组织工程中富集骨髓间充质干细胞的E7肽功能化Ti6Al4V合金
E7 peptide-functionalized Ti6Al4V alloy for BMSC enrichment in bone tissue engineering.
作者信息
Man Zhentao, Li Tao, Zhang Laibo, Yuan Lin, Wu Changshun, Li Ping, Sun Shui, Li Wei
机构信息
Department of Joint Surgery, Shandong Provincial Hospital Affiliated to Shandong University Jinan 250021, Shandong Province, P. R. China.
出版信息
Am J Transl Res. 2018 Aug 15;10(8):2480-2490. eCollection 2018.
Abstract
Ti6Al4V alloy is widely used for hip joint prostheses, however owing to its lack of biomimetic surface properties, it often suffers from poor osseointegration. It is well known that bone mesenchymal stem cells (BMSCs) play an important role in the osseointegration of the host bone and joint prostheses. One promising approach to improving the osseointegration of joint prostheses is to enrich the number of BMSCs at the periprosthetic site. Previous studies have reported that BMSC specific affinity peptide E7, can specifically enrich BMSCs. However, to date, few studies have reported the use of E7 in bone tissue engineering. In this study, we conjugated E7 peptide to Ti6Al4V alloy to fabricate a scaffold (BTS) to improve the biocompatibility of the alloy. E7 peptide efficiently improved the adhesion of BMSCs to Ti6Al4V alloy. In addition, the BTS scaffold was more conducive to osteogenesis than the RGD-functionalized and non-functionalized control scaffolds. The functional BTS scaffold could pave the way for designing functional joint prostheses, which promote osseointegration between the host bone and implant.
摘要
Ti6Al4V合金被广泛用于髋关节假体,然而,由于其缺乏仿生表面特性,它常常存在骨整合不良的问题。众所周知,骨间充质干细胞(BMSCs)在宿主骨与关节假体的骨整合中起重要作用。一种改善关节假体骨整合的有前景的方法是在假体周围部位富集BMSCs的数量。先前的研究报道,BMSC特异性亲和肽E7能够特异性地富集BMSCs。然而,迄今为止,很少有研究报道E7在骨组织工程中的应用。在本研究中,我们将E7肽与Ti6Al4V合金结合以制备一种支架(BTS),从而改善该合金的生物相容性。E7肽有效地提高了BMSCs对Ti6Al4V合金的粘附。此外,BTS支架比RGD功能化和非功能化的对照支架更有利于成骨。功能性BTS支架可为设计促进宿主骨与植入物之间骨整合的功能性关节假体铺平道路。
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2
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3
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4
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8
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