Knabe Christine, Stiller Michael, Kampschulte Marian, Wilbig Janka, Peleska Barbara, Günster Jens, Gildenhaar Renate, Berger Georg, Rack Alexander, Linow Ulf, Heiland Max, Rendenbach Carsten, Koerdt Steffen, Steffen Claudius, Houshmand Alireza, Xiang-Tischhauser Li, Adel-Khattab Doaa
Department of Experimental Orofacial Medicine, Philipps University Marburg, Marburg, Germany.
Department of Prosthodontics, Philipps University Marburg, Marburg, Germany.
Front Bioeng Biotechnol. 2023 Jun 15;11:1221314. doi: 10.3389/fbioe.2023.1221314. eCollection 2023.
Recently, efforts towards the development of patient-specific 3D printed scaffolds for bone tissue engineering from bioactive ceramics have continuously intensified. For reconstruction of segmental defects after subtotal mandibulectomy a suitable tissue engineered bioceramic bone graft needs to be endowed with homogenously distributed osteoblasts in order to mimic the advantageous features of vascularized autologous fibula grafts, which represent the standard of care, contain osteogenic cells and are transplanted with the respective blood vessel. Consequently, inducing vascularization early on is pivotal for bone tissue engineering. The current study explored an advanced bone tissue engineering approach combining an advanced 3D printing technique for bioactive resorbable ceramic scaffolds with a perfusion cell culture technique for pre-colonization with mesenchymal stem cells, and with an intrinsic angiogenesis technique for regenerating critical size, segmental discontinuity defects applying a rat model. To this end, the effect of differing Si-CAOP (silica containing calcium alkali orthophosphate) scaffold microarchitecture arising from 3D powder bed printing (RP) or the Schwarzwalder Somers (SSM) replica fabrication technique on vascularization and bone regeneration was analyzed . In 80 rats 6-mm segmental discontinuity defects were created in the left femur. Embryonic mesenchymal stem cells were cultured on RP and SSM scaffolds for 7d under perfusion to create Si-CAOP grafts with terminally differentiated osteoblasts and mineralizing bone matrix. These scaffolds were implanted into the segmental defects in combination with an arteriovenous bundle (AVB). Native scaffolds without cells or AVB served as controls. After 3 and 6 months, femurs were processed for angio-µCT or hard tissue histology, histomorphometric and immunohistochemical analysis of angiogenic and osteogenic marker expression. At 3 and 6 months, defects reconstructed with RP scaffolds, cells and AVB displayed a statistically significant higher bone area fraction, blood vessel volume%, blood vessel surface/volume, blood vessel thickness, density and linear density than defects treated with the other scaffold configurations. Taken together, this study demonstrated that the AVB technique is well suited for inducing adequate vascularization of the tissue engineered scaffold graft in segmental defects after 3 and 6 months, and that our tissue engineering approach employing 3D powder bed printed scaffolds facilitated segmental defect repair.
最近,利用生物活性陶瓷开发用于骨组织工程的个性化3D打印支架的工作不断加强。对于下颌骨次全切除术后节段性缺损的重建,合适的组织工程生物陶瓷骨移植体需要含有均匀分布的成骨细胞,以模仿血管化自体腓骨移植的优势特征,后者是目前的标准治疗方法,含有成骨细胞并与相应血管一起移植。因此,早期诱导血管生成对于骨组织工程至关重要。本研究探索了一种先进的骨组织工程方法,该方法将用于生物活性可吸收陶瓷支架的先进3D打印技术与用于间充质干细胞预定植的灌注细胞培养技术以及用于再生临界尺寸节段性连续性缺损的内在血管生成技术相结合,并应用大鼠模型进行研究。为此,分析了由3D粉末床打印(RP)或施瓦茨瓦尔德·萨默斯(SSM)复制制造技术产生的不同Si-CAOP(含硅碱式磷酸钙)支架微结构对血管生成和骨再生的影响。在80只大鼠的左股骨中制造6毫米节段性连续性缺损。胚胎间充质干细胞在灌注条件下在RP和SSM支架上培养7天,以创建具有终末分化成骨细胞和矿化骨基质的Si-CAOP移植物。这些支架与动静脉束(AVB)一起植入节段性缺损处。没有细胞或AVB的天然支架用作对照。3个月和6个月后,对股骨进行血管造影微计算机断层扫描(angio-µCT)或硬组织组织学检查、血管生成和成骨标记物表达的组织形态计量学和免疫组织化学分析。在3个月和6个月时,用RP支架、细胞和AVB重建的缺损与用其他支架配置处理的缺损相比,骨面积分数、血管体积百分比、血管表面积/体积、血管厚度、密度和线性密度在统计学上显著更高。综上所述,本研究表明,AVB技术非常适合在3个月和6个月后诱导组织工程支架移植物在节段性缺损中实现充分的血管生成,并且我们采用3D粉末床打印支架的组织工程方法促进了节段性缺损的修复。
