Department of Materials Engineering, Isfahan University of Technology, Isfahan 84156-83111, Iran.
Department of Anatomical Sciences and Molecular Biology, School of Medicine, Isfahan University of Medical Sciences, Isfahan, Iran.
Int J Biol Macromol. 2024 Feb;258(Pt 1):128917. doi: 10.1016/j.ijbiomac.2023.128917. Epub 2023 Dec 20.
Critical sized craniofacial defects are among the most challenging bone defects to repair, due to the anatomical complexity and aesthetic importance. In this study, a polylactic acid/hardystonite-graphene oxide (PLA/HTGO) scaffold was fabricated through 3D printing. In order to upgrade the 3D printed scaffold to a highly porous scaffold, its channels were filled with pectin-quaternized chitosan (Pec-QCs) polyelectrolyte solution containing 0 or 20 mg/mL of simvastatin (Sim) and then freeze-dried. These scaffolds were named FD and FD-Sim, respectively. Also, similar PLA/HTGO scaffolds were prepared and dip coated with Pec-QCs solution containing 0 or 20 mg/mL of Sim and were named DC and DC-Sim, respectively. The formation of macro/microporous structure was confirmed by morphological investigations. The release of Sim from DC-Sim and FD-Sim scaffolds after 28 days was measured as 77.40 ± 5.25 and 86.02 ± 3.63 %, respectively. Cytocompatibility assessments showed that MG-63 cells had the highest proliferation, attachment and spread on the Sim containing scaffolds, especially FD-Sim. In vivo studies on a rat calvarial defect model revealed that an almost complete recovery occurred in the group treated with FD-Sim scaffold after 8 weeks and the defect was filled with newly formed bone. The results of this study acknowledge that the FD-Sim scaffold can be a perfect candidate for calvarial defect repair.
临界尺寸颅面缺损是最难修复的骨缺损之一,这是由于其解剖结构复杂且对美观度要求较高。在本研究中,通过 3D 打印技术制备了聚乳酸/硬硅钙石-氧化石墨烯(PLA/HTGO)支架。为了将 3D 打印支架升级为具有高多孔结构的支架,其通道中填充了含有 0 或 20mg/mL 辛伐他汀(Sim)的果胶-壳聚糖(Pec-QCs)聚电解质溶液,然后进行冷冻干燥。这些支架分别命名为 FD 和 FD-Sim。此外,还制备了类似的 PLA/HTGO 支架,并采用含有 0 或 20mg/mL Sim 的 Pec-QCs 溶液进行浸涂,分别命名为 DC 和 DC-Sim。通过形态学研究证实了宏观/微观多孔结构的形成。在第 28 天时,从 DC-Sim 和 FD-Sim 支架中释放 Sim 的量分别为 77.40±5.25%和 86.02±3.63%。细胞相容性评估表明,MG-63 细胞在含有 Sim 的支架上具有最高的增殖、附着和扩散能力,尤其是 FD-Sim。在大鼠颅骨缺损模型的体内研究中,在接受 FD-Sim 支架治疗的组中,8 周后几乎完全恢复,缺损部位被新形成的骨填充。本研究结果表明,FD-Sim 支架可作为颅骨缺损修复的理想候选支架。
