Laboratory for Biomechanics and Biomaterials, Department of Orthopaedic Surgery, Hannover Medical School, Anna-von-Borries-Straße 1-7, Hannover 30625, Germany.
Laboratory for Biomechanics and Biomaterials, Department of Orthopaedic Surgery, Hannover Medical School, Anna-von-Borries-Straße 1-7, Hannover 30625, Germany.
Acta Biomater. 2022 Aug;148:389-404. doi: 10.1016/j.actbio.2022.06.005. Epub 2022 Jun 9.
Open-porous scaffolds made of W4 and WZ21 fibres were evaluated to analyse their potential as an implant material. WZ21 scaffolds without any surface modification or coating, showed promising mechanical properties which were comparable to the W4 scaffolds tested in previous studies. Eudiometric testing results were dependent on the experimental setup, with corrosion rates differing by a factor of 3. Cytotoxicity testing of WZ21 showed sufficient cytocompatibility. The corrosion behavior of the WZ21 scaffolds in different cell culture media are indicating a selective dealloying of elements from the magnesium scaffold by different solutions. Long term in-vivo studies were using 24 W4 scaffolds and 12 WZ21 scaffolds, both implanted in rabbit femoral condyles. The condyles and important inner organs were explanted after 6, 12 and 24 weeks and analyzed. The in-vivo corrosion rate of the WZ21 scaffolds calculated by microCT-based volume loss was up to 49 times slower than the in-vitro corrosion rate based on weight loss. Intramembranous bone formation within the scaffolds of both alloys was revealed, however a low corrosion rate and formation of gas cavities at initial time points were also detected. No systemic or local toxicity could be observed. Investigations by μ-XRF did not reveal accumulation of yttrium in the neighboring tissue. In summary, the magnesium scaffold´s performance is biocompatible, but would benefit from a surface modification, such as a coating to obtain lower the initial corrosion rates, and hereby establish a promising open-porous implant material for load-bearing applications. STATEMENT OF SIGNIFICANCE: Magnesium is an ideal temporary implant material for non-load bearing applications like bigger bone defects, since it degrades in the body over time. Here we developed and tested in vitro and in a rabbit model in vivo degradable open porous scaffolds made of sintered magnesium W4 and WZ21 short fibres. These scaffolds allow the ingrowth of cells and blood vessels to promote bone healing and regeneration. Both fibre types showed in vitro sufficient cytocompatibility and proliferation rates and in vivo, no systemic toxicity could be detected. At the implantation site, intramembranous bone formation accompanied by ingrowth of supplying blood vessels within the scaffolds of both alloys could be detected.
多孔支架由 W4 和 WZ21 纤维制成,用于分析其作为植入材料的潜力。未经任何表面改性或涂层处理的 WZ21 支架表现出有前景的机械性能,可与之前研究中测试的 W4 支架相媲美。气体渗透测试结果取决于实验设置,腐蚀速率相差 3 倍。WZ21 的细胞毒性测试表明其具有足够的细胞相容性。WZ21 支架在不同细胞培养基中的腐蚀行为表明,不同溶液会选择性地从镁支架中去除元素。长期体内研究使用了 24 个 W4 支架和 12 个 WZ21 支架,均植入兔股骨髁。在 6、12 和 24 周后取出髁和重要的内部器官进行分析。通过基于微 CT 的体积损失计算的 WZ21 支架体内腐蚀速率比基于重量损失的体外腐蚀速率慢 49 倍。两种合金支架内均发现有膜内骨形成,但也检测到初始时间点腐蚀速率低和气体空腔形成。未观察到全身或局部毒性。μ-XRF 研究未发现钇在邻近组织中的积累。总之,镁支架的性能具有生物相容性,但需要进行表面改性,例如涂层,以降低初始腐蚀速率,并由此建立一种有前途的用于承重应用的多孔植入材料。 意义声明:镁是一种理想的临时植入材料,适用于非承重应用,如较大的骨缺损,因为它会随着时间的推移在体内降解。在这里,我们开发并测试了体外和兔模型体内由烧结镁 W4 和 WZ21 短纤维制成的可降解多孔支架。这些支架允许细胞和血管生长,以促进骨愈合和再生。两种纤维类型在体外均显示出足够的细胞相容性和增殖率,并且在体内未检测到全身毒性。在植入部位,两种合金支架内均检测到膜内骨形成,同时有供应血管向内生长。
