Xu Yichi, Peng Jiang, Richards Geoff, Lu Shibi, Eglin David
Lab of Orthopaedics of Department of Orthopaedics, Chinese PLA General Hospital, Beijing Key Lab of Regenerative Medicine in Orthopaedics, Key Lab of Musculoskeletal Trauma & War Injuries of PLA, Beijing 100853, China.
AO Research Institute Davos, Clavadelerstrasse 8, 7270 Davos Platz, Switzerland.
J Orthop Translat. 2019 Jun 25;18:128-141. doi: 10.1016/j.jot.2019.05.003. eCollection 2019 Jul.
Our study reports the optimization of electrospray human bone marrow stromal cell (hBMSCs)-embedded alginate-gelatin (Alg-Gel, same as following) microspheres for the purpose of their assembly in 3D-printed poly(ε-caprolactone) (PCL) scaffold for the fabrication of a mechanically stable and biological supportive tissue engineering cartilage construct.
The fabrication of the Alg-Gel microspheres using an electrospray technique was optimized in terms of polydispersity, yield of microspheres and circularity and varying fabrication conditions. PCL scaffolds were designed and printed by melt extrusion. Then, four groups were set: Alg-hBMSC microspheres cultured in the 2D well plate (Alg-hBMSCs+2D) group, Alg-Gel-hBMSC microspheres cultured in the 2D well plate (Alg-Gel-hBMSCs+2D) group, Alg-Gel-hBMSC microspheres embedded in PCL scaffold cultured in the 2D well plate (Alg-Gel-hBMSCs+2D) group and Alg-Gel-hBMSCs microspheres cultured in the 3D bioreactor (Alg-Gel-hBMSCs+3D) group. Cell viability, proliferation and chondrogenic differentiation were evaluated, and mechanical test was performed.
Nonaggregated, low polydispersity and almost spherical microspheres of average diameter of 200-300 μm were produced with alginate 1.5 w: v%, gelatin (Type B) concentration of 0.5 w: v % and CaCl coagulating bath concentration of 3.0 w: v %, using 30G needle size and 8 kV and 0.6 bar voltage and air pressure, respectively. Alginate with gelatin hydrogel improved viability and promoted hBMSC proliferation better than alginate microspheres. Interestingly, hBMSCs embedded in microspheres assembled in 3D-printed PCL scaffold and cultured in a 3D bioreactor were more proliferative in comparison to the previous two groups (p < 0.05). Similarly, the GAG content, GAG/DNA ratio as well as Coll 2 and Aggr gene expression were increased in the last two groups.
Optimization of hBMSC-embedded Alg-Gel microspheres produced by electrospray has been performed. The Alg-Gel composition selected allows conservation of hBMSC viability and supports proliferation and matrix deposition. The possibility to seed and assemble microspheres in designed 3D-printed PCL scaffolds for the fabrication of a mechanically stable and biological supportive tissue engineering cartilage construct was demonstrated.
We optimize and demonstrate that electrospray microsphere fabrication is a cytocompatible and facile process to produce the hBMSC-embedded microsize tissue-like particles that can easily be assembled into a stable construct. This finding could have application in the development of mechanically competent stem cell-based tissue engineering of cartilage regeneration.
我们的研究报告了对电喷雾法制备的负载人骨髓间充质干细胞(hBMSCs)的海藻酸钠-明胶(Alg-Gel,下同)微球进行优化,以便将其组装到3D打印的聚己内酯(PCL)支架中,用于制造机械稳定且具有生物支持性的组织工程软骨构建体。
在多分散性、微球产率和圆度以及不同的制备条件方面,对使用电喷雾技术制备Alg-Gel微球进行了优化。通过熔融挤出设计并打印PCL支架。然后,设置四组:二维孔板中培养的Alg-hBMSC微球(Alg-hBMSCs+2D)组、二维孔板中培养的Alg-Gel-hBMSC微球(Alg-Gel-hBMSCs+2D)组、二维孔板中培养的嵌入PCL支架的Alg-Gel-hBMSC微球(Alg-Gel-hBMSCs+2D)组和三维生物反应器中培养的Alg-Gel-hBMSCs微球(Alg-Gel-hBMSCs+3D)组。评估细胞活力、增殖和软骨形成分化,并进行力学测试。
使用1.5 w:v%的海藻酸钠、0.5 w:v%的明胶(B型)浓度和3.0 w:v%的CaCl₂凝固浴浓度,分别采用30G针头尺寸、8 kV电压和0.6 bar气压,制备出了平均直径为200-300μm的非聚集、低多分散性且几乎呈球形的微球。与海藻酸钠微球相比,海藻酸钠与明胶水凝胶提高了细胞活力并更好地促进了hBMSC增殖。有趣的是,与前两组相比,嵌入微球并组装到3D打印PCL支架中且在三维生物反应器中培养的hBMSC增殖更多(p<0.05)。同样,后两组中的糖胺聚糖(GAG)含量、GAG/DNA比率以及Ⅱ型胶原蛋白(Coll 2)和聚集蛋白聚糖(Aggr)基因表达均增加。
已对电喷雾法制备的负载hBMSC的Alg-Gel微球进行了优化。所选择的Alg-Gel组合物能够保持hBMSC活力,并支持其增殖和基质沉积。证明了将微球接种并组装到设计的3D打印PCL支架中以制造机械稳定且具有生物支持性的组织工程软骨构建体的可能性。
我们优化并证明电喷雾微球制备是一种细胞相容性良好且简便的方法,可用于生产负载hBMSC的微米级组织样颗粒,这些颗粒能够轻松组装成稳定的构建体。这一发现可能应用于基于干细胞的具有机械性能的软骨再生组织工程的开发。
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