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经碱处理或酸处理的3D粉末打印磷酸钙镁骨水泥支架的降解行为与骨整合比较

Comparison of degradation behavior and osseointegration of 3D powder-printed calcium magnesium phosphate cement scaffolds with alkaline or acid post-treatment.

作者信息

Kowalewicz Katharina, Waselau Anja-Christina, Feichtner Franziska, Schmitt Anna-Maria, Brückner Manuel, Vorndran Elke, Meyer-Lindenberg Andrea

机构信息

Clinic for Small Animal Surgery and Reproduction, Ludwig-Maximilians-University of Munich, Munich, Germany.

Department for Functional Materials in Medicine and Dentistry, University of Würzburg, Würzburg, Germany.

出版信息

Front Bioeng Biotechnol. 2022 Sep 28;10:998254. doi: 10.3389/fbioe.2022.998254. eCollection 2022.

DOI:10.3389/fbioe.2022.998254
PMID:36246367
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9554004/
Abstract

Due to the positive effects of magnesium substitution on the mechanical properties and the degradation rate of the clinically well-established calcium phosphate cements (CPCs), calcium magnesium phosphate cements (CMPCs) are increasingly being researched as bone substitutes. A post-treatment alters the materials' physical properties and chemical composition, reinforcing the structure and modifying the degradation rate. By alkaline post-treatment with diammonium hydrogen phosphate (DAHP, (NH)HPO), the precipitation product struvite is formed, while post-treatment with an acidic phosphate solution [e.g., phosphoric acid (PA, HPO)] results in precipitation of newberyite and brushite. However, little research has yet been conducted on newberyite as a bone substitute and PA post-treatment of CMPCs has not been described in the accessible literature so far. Therefore, in the present study, the influence of an alkaline (DAHP) or acid (PA) post-treatment on the biocompatibility, degradation behavior, and osseointegration of cylindrical scaffolds ( = 5.1 mm, = 4.2 mm) produced from the ceramic cement powder CaMg(PO) by the advantageous manufacturing technique of three-dimensional (3D) powder printing was investigated . Scaffolds of the material groups Mg225d (DAHP post-treatment) and Mg225p (PA post-treatment) were implanted into the cancellous part of the lateral femoral condyles in rabbits. They were evaluated up to 24 weeks by regular clinical, X-ray, micro-computed tomographic (µCT), and histological examinations as well as scanning electron microscopy (SEM) and energy dispersive X-ray spectroscopy (EDX) analysis and compared with tricalcium phosphate (TCP). All materials showed excellent biocompatibility and rapid osseointegration. While TCP degraded only slightly, the CMPCs showed almost complete degradation. Mg225d demonstrated significantly faster loss of form and demarcability from surrounding bone, scaffold volume reduction, and significantly greater degradation on the side towards the bone marrow than to the cortex than Mg225p. Simultaneously, numerous bone trabeculae have grown into the implantation site. While these were mostly located on the side towards the cortex in Mg225d, they were more evenly distributed in Mg225p and showed almost the same structural characteristics as physiological bone after 24 weeks in Mg225p. Based on these results, the acid post-treated 3D powder-printed Mg225p is a promising degradable bone substitute that should be further investigated.

摘要

由于镁替代对临床常用的磷酸钙骨水泥(CPCs)的力学性能和降解速率具有积极影响,磷酸钙镁骨水泥(CMPCs)作为骨替代物正受到越来越多的研究。后处理会改变材料的物理性质和化学成分,增强结构并改变降解速率。通过用磷酸氢二铵(DAHP,(NH₄)₂HPO₄)进行碱性后处理,会形成鸟粪石沉淀产物,而用酸性磷酸盐溶液[例如磷酸(PA,H₃PO₄)]进行后处理则会导致新磷钙石和透钙磷石沉淀。然而,关于新磷钙石作为骨替代物的研究还很少,并且目前可获取的文献中尚未描述对CMPCs进行PA后处理的情况。因此,在本研究中,研究了碱性(DAHP)或酸性(PA)后处理对通过三维(3D)粉末打印这一优势制造技术由陶瓷水泥粉末CaMg(PO₄)₂制成的圆柱形支架(直径 = 5.1 mm,高度 = 4.2 mm)的生物相容性、降解行为和骨整合的影响。将材料组Mg225d(DAHP后处理)和Mg225p(PA后处理)的支架植入兔股骨外侧髁的松质骨部分。通过定期的临床、X射线、显微计算机断层扫描(µCT)和组织学检查以及扫描电子显微镜(SEM)和能量色散X射线光谱(EDX)分析对它们进行长达24周的评估,并与磷酸三钙(TCP)进行比较。所有材料均表现出优异的生物相容性和快速的骨整合。虽然TCP仅轻微降解,但CMPCs几乎完全降解。与Mg225p相比,Mg225d在形状损失和与周围骨的分界性方面明显更快,支架体积减小,并且朝向骨髓一侧的降解明显大于朝向皮质一侧。同时,大量骨小梁已长入植入部位。虽然在Mg225d中这些骨小梁大多位于朝向皮质的一侧,但在Mg225p中它们分布更均匀,并且在Mg225p中24周后显示出与生理骨几乎相同的结构特征。基于这些结果,经酸后处理的3D粉末打印Mg225p是一种有前景的可降解骨替代物,应进一步研究。

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2
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3
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J Appl Biomater Funct Mater. 2022 Jan-Dec;20:22808000221078168. doi: 10.1177/22808000221078168.
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