Academy for Advanced Interdisciplinary Studies, Peking University, Beijing 100871, China.
Department of Orthopedics, The Fifth Affiliated Hospital of Guangzhou Medical University, Guangdong 510700, China.
Acta Biomater. 2019 Oct 15;98:50-66. doi: 10.1016/j.actbio.2019.03.009. Epub 2019 Mar 7.
Proper alloying magnesium with element scandium (Sc) could transform its microstructure from α phase with hexagonal closed-packed (hcp) structure into β phase with body-cubic centered (bcc) structure. In the present work, the Mg-30 wt% Sc alloy with single α phase, dual phases (α + β) or β phase microstructure were developed by altering the heat-treatment routines and their suitability for usage within bone was comprehensively investigated. The β phased Mg-30 wt% Sc alloy showed the best mechanical performance with ultimate compressive strength of 603 ± 39 MPa and compressive strain of 31 ± 3%. In vitro degradation test showed that element scandium could effectively incorporate into the surface corrosion product layer, form a double-layered structure, and further protect the alloy matrix. No cytotoxic effect was observed for both single α phased and β phased Mg-30 wt% Sc alloys on MC3T3 cell line. Moreover, the β phased Mg-30 wt%Sc alloy displayed acceptable corrosion resistance in vivo (0.06 mm y) and maintained mechanical integrity up to 24 weeks. The degradation process did not significantly influence the hematology indexes of inflammation, hepatic or renal functions. The bone-implant contact ratio of 75 ± 10% after 24 weeks implied satisfactory integration between β phased Mg-30 wt%Sc alloy and the surrounding bone. These findings indicate a potential usage of the bcc-structured Mg-Sc alloy within bone and might provide a new strategy for future biomedical magnesium alloy design. STATEMENT OF SIGNIFICANCE: Scandium is the only rare earth element that can transform the matrix of magnesium alloy into bcc structure, and Mg-30 wt%Sc alloy had been recently reported to exhibit shape memory effect. The aim of the present work is to study the feasibility of Mg-30 wt%Sc alloy with different constitutional phases (single α phase, single β phase or dual phases (α + β)) as biodegradable orthopedic implant by in vitro and in vivo testings. Our findings showed that β phased Mg-30 wt%Sc alloy which is of bcc structure exhibited improved strength and superior in vivo degradation performance (0.06 mm y). No cytotoxicity and systematic toxicity were shown for β phased Mg-30 wt%Sc alloy on MC3T3 cell model and rat organisms. Moreover, good osseointegration, limited hydrogen gas release and maintained mechanical integrity were observed after 24 weeks' implantation into the rat femur bone.
适当添加元素钪(Sc)可以将镁的微观结构从具有六方密堆积(hcp)结构的α相转变为具有体心立方(bcc)结构的β相。在本工作中,通过改变热处理程序,开发了具有单相α、双相(α+β)或β相微观结构的 Mg-30wt%Sc 合金,并全面研究了其在骨骼中的适用性。β相 Mg-30wt%Sc 合金具有最佳的力学性能,其抗压强度高达 603±39MPa,压缩应变达到 31±3%。体外降解试验表明,钪元素可有效掺入表面腐蚀产物层,形成双层结构,进一步保护合金基体。在 MC3T3 细胞系上,单相α相和β相 Mg-30wt%Sc 合金均无细胞毒性。此外,β相 Mg-30wt%Sc 合金在体内具有良好的耐腐蚀性(0.06mm/y),并在 24 周内保持机械完整性。降解过程对炎症、肝肾功能的血液学指标没有显著影响。24 周后,骨-植入物接触率为 75±10%,表明β相 Mg-30wt%Sc 合金与周围骨具有良好的整合。这些发现表明 bcc 结构的 Mg-Sc 合金在骨骼中有潜在的应用,并可能为未来生物医学镁合金设计提供新的策略。
钪是唯一能将镁合金基体转变为 bcc 结构的稀土元素,而 Mg-30wt%Sc 合金最近已被报道具有形状记忆效应。本工作的目的是通过体外和体内试验研究不同组织相(单相α相、单相β相或双相(α+β))的 Mg-30wt%Sc 合金作为可生物降解的骨科植入物的可行性。我们的研究结果表明,具有 bcc 结构的β相 Mg-30wt%Sc 合金具有较高的强度和优越的体内降解性能(0.06mm/y)。β相 Mg-30wt%Sc 合金在 MC3T3 细胞模型和大鼠机体上无细胞毒性和系统毒性。此外,在大鼠股骨中植入 24 周后,观察到良好的骨整合、有限的氢气释放和保持机械完整性。
