Univ Lyon, INSA Lyon, UCB Lyon 1, CNRS, MATEIS UMR 5510, Bât. Blaise Pascal, 7 Avenue Jean Capelle, 69621Villeurbanne, France.
RMS Foundation, Bischmattstrasse 12, 2544 Bettlach, Switzerland.
Acta Biomater. 2019 Apr 15;89:391-402. doi: 10.1016/j.actbio.2019.02.045. Epub 2019 Mar 1.
The efficiency of calcium phosphate (CaP) bone substitutes can be improved by tuning their resorption rate. The influence of both crystal orientation and ion doping on resorption is here investigated for beta-tricalcium phosphate (β-TCP). Non-doped and Mg-doped (1 and 6 mol%) sintered β-TCP samples were immersed in acidic solution (pH 4.4) to mimic the environmental conditions found underneath active osteoclasts. The surfaces of β-TCP samples were observed after acid-etching and compared to surfaces after osteoclastic resorption assays. β-TCP grains exhibited similar patterns with characteristic intra-crystalline pillars after acid-etching and after cell-mediated resorption. Electron BackScatter Diffraction analyses, coupled with Scanning Electron Microscopy, Inductively Coupled Plasma-Mass Spectrometry and X-Ray Diffraction, demonstrated the influence of both grain orientation and doping on the process and kinetics of resorption. Grains with c-axis nearly perpendicular to the surface were preferentially etched in non-doped β-TCP samples, whereas all grains with simple axis (a, b or c) nearly normal to the surface were etched in 6 mol% Mg-doped samples. In addition, both the dissolution rate and the percentage of etched surface were lower in Mg-doped specimens. Finally, the alignment direction of the intra-crystalline pillars was correlated with the preferential direction for dissolution. STATEMENT OF SIGNIFICANCE: The present work focuses on the resorption behavior of calcium phosphate bioceramics. A simple and cost-effective alternative to osteoclast culture was implemented to identify which material features drive resorption. For the first time, it was demonstrated that crystal orientation, measured by Electron Backscatter Diffraction, is the discriminating factor between grains, which resorbed first, and grains, which resorbed slower. It also elucidated how resorption kinetics can be tuned by doping β-tricalcium phosphate with ions of interest. Doping with magnesium impacted lattice parameters. Therefore, the crystal orientations, which preferentially resorbed, changed, explaining the solubility decrease. These important findings pave the way for the design of optimized bone graft substitutes with tailored resorption kinetics.
磷酸钙 (CaP) 骨替代物的效率可以通过调整其吸收率来提高。本研究旨在探讨晶体取向和离子掺杂对β-磷酸三钙 (β-TCP) 吸收率的影响。将未掺杂和掺杂 1 和 6 mol% Mg 的β-TCP 烧结样品浸入酸性溶液 (pH 4.4) 中,以模拟在活性破骨细胞下发现的环境条件。用酸蚀刻后观察β-TCP 样品的表面,并将其与破骨细胞介导的吸收后表面进行比较。β-TCP 晶粒在酸蚀刻后和细胞介导的吸收后都表现出相似的特征,具有特征性的晶内支柱图案。电子背散射衍射分析与扫描电子显微镜、电感耦合等离子体质谱和 X 射线衍射相结合,证明了晶粒取向和掺杂对吸收过程和动力学的影响。在未掺杂的β-TCP 样品中,c 轴几乎垂直于表面的晶粒优先被蚀刻,而在 6 mol% Mg 掺杂的样品中,所有具有简单轴(a、b 或 c)几乎垂直于表面的晶粒都被蚀刻。此外,Mg 掺杂样品的溶解速率和被蚀刻表面的百分比都较低。最后,晶内支柱的排列方向与优先溶解方向相关。本研究重点研究了磷酸钙生物陶瓷的吸收行为。采用一种简单且经济有效的破骨细胞培养替代方法来确定哪些材料特性决定了吸收率。首次证明,电子背散射衍射测量的晶体取向是决定哪些晶粒首先吸收以及哪些晶粒吸收较慢的区别因素。它还阐明了如何通过用感兴趣的离子掺杂β-磷酸三钙来调整吸收率动力学。用镁掺杂会影响晶格参数。因此,优先吸收的晶体取向发生了变化,解释了溶解度的降低。这些重要发现为设计具有定制吸收率动力学的优化骨移植物替代品铺平了道路。
