Lam Alan Tin-Lun, Li Jian, Toh Jessica Pei-Wen, Sim Eileen Jia-Hui, Chen Allen Kuan-Liang, Chan Jerry Kok-Yen, Choolani Mahesh, Reuveny Shaul, Birch William R, Oh Steve Kah-Weng
Stem Cell Group, Bioprocessing Technology Institute, Agency for Science, Technology and Research (A*STAR), Singapore.
Institute of Materials Research and Engineering, Agency for Science, Technology and Research (A*STAR), Singapore.
Cytotherapy. 2017 Mar;19(3):419-432. doi: 10.1016/j.jcyt.2016.11.009. Epub 2016 Dec 22.
Large numbers of human mesenchymal stromal cells (MSCs) used for a variety of applications in tissue engineering and cell therapy can be generated by scalable expansion in a bioreactor using microcarriers (MCs) systems. However, the enzymatic digestion process needed to detach cells from the growth surface can affect cell viability and potentially the potency and differentiation efficiency. Thus, the main aim of our study was to develop biocompatible and biodegradable MCs that can support high MSC yields while maintaining their differentiation capability and potency. After cell expansion, the cells that covered MCs can be directly implanted in vivo without the need for cell harvesting or use of scaffold. Poly-ε-caprolactone (PCL) is known as a biocompatible and biodegradable material. However, it cannot be used for generation of MCs because its high density (1.14 g/cm) would exclude its applicability for suspension MCs in stirred reactors. In this article, we describe expansion and potency of MSCs propagated on low-density (1.06 g/cm) porous PCL MCs coated with extracellular matrices (LPCLs) in suspended stirred reactors. Using these LPCLs, cell yields of about 4 × 10 cells/cm and 7- to 10-fold increases were obtained using four different MSC lines (bone marrow, cord blood, fetal and Wharton's jelly). These yields were comparable with those obtained using non-degradable MCs (Cytodex 3) and higher than two-dimensional monolayer (MNL) cultures. A fed-batch process, which demonstrated faster cell expansion (4.5 × 10 cells/cm in 5 days as compared with 7 days in batch culture) and about 70% reduction in growth media usage, was developed and scaled up from 100-mL spinner flask to 1-L controlled bioreactor. Surface marker expression, trilineage differentiation and clonogenic potential of the MSCs expanded on LPCL were not affected. Cytokine secretion kinetics, which occurred mostly during late logarithmic phase, was usually comparable with that obtained in Cytodex 3 cultures and higher than MNL cultures. In conclusion, biodegradable LPCL can be used to efficiently expand a variety of MSC lines in stirred scalable reactors in a cost-effective manner while maintaining surface markers expression, differentiation capability and high levels of cytokine secretion. This study is the first step in testing these cell-biodegradable porous MC aggregates for tissue engineering and cell therapy, such as bone and cartilage regeneration, or wound healing.
用于组织工程和细胞治疗各种应用的大量人间充质基质细胞(MSCs),可以通过在生物反应器中使用微载体(MCs)系统进行可扩展扩增来产生。然而,将细胞从生长表面分离所需的酶消化过程会影响细胞活力,并可能影响细胞的效能和分化效率。因此,我们研究的主要目的是开发生物相容性和可生物降解的微载体,其能够在维持间充质基质细胞分化能力和效能的同时支持高产量的细胞生成。细胞扩增后,覆盖在微载体上的细胞可直接植入体内,无需收获细胞或使用支架。聚ε-己内酯(PCL)是一种已知的生物相容性和可生物降解材料。然而,它不能用于生成微载体,因为其高密度(1.14 g/cm³)会排除其在搅拌式反应器中用于悬浮微载体的适用性。在本文中,我们描述了在悬浮搅拌式反应器中,在涂有细胞外基质的低密度(1.06 g/cm³)多孔PCL微载体(LPCLs)上扩增的间充质基质细胞的扩增情况和效能。使用这些LPCLs,利用四种不同的间充质基质细胞系(骨髓、脐带血、胎儿和沃顿胶)获得了约4×10⁶个细胞/cm³的细胞产量以及7至10倍的增长。这些产量与使用不可降解微载体(Cytodex 3)获得的产量相当,且高于二维单层(MNL)培养。开发了一种补料分批培养工艺,该工艺显示出更快的细胞扩增速度(5天内达到4.5×10⁶个细胞/cm³,而分批培养为7天),并且生长培养基的使用量减少了约70%,并从100 mL转瓶扩大到1 L可控生物反应器。在LPCL上扩增的间充质基质细胞的表面标志物表达、三系分化和克隆形成潜力均未受到影响。细胞因子分泌动力学大多发生在对数后期,通常与在Cytodex 3培养中获得的相当,且高于MNL培养。总之,可生物降解的LPCL可用于在搅拌式可扩展反应器中以经济有效的方式高效扩增多种间充质基质细胞系,同时维持表面标志物表达、分化能力和高水平的细胞因子分泌。本研究是测试这些细胞可生物降解的多孔微载体聚集体用于组织工程和细胞治疗(如骨和软骨再生或伤口愈合)的第一步。
