Modification and qualification of a stirred single-use bioreactor for the improved expansion of human mesenchymal stem cells at benchtop scale

Pharmaceutical bioprocessing Pub Date : 2014-10-17 DOI:10.4155/PBP.14.29

Valentin Jossen, S. Kaiser, Carmen Schirmaier, J. Herrmann, A. Tappe, D. Eibl, A. Siehoff, C. Bos, R. Eibl

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引用次数: 26

Abstract

Background: To improve cultivation conditions for human bone-marrow-derived mesenchymal stem cells, we redesigned the commercially available UniVessel® SU bioreactor using results obtained from computational fluid dynamics. The goal was to produce ≥1 × 109 cells and to achieve expansion factors ≥30. Screening studies suggested that microcarrier solid fractions of at least 0.3% are required to reach the appropriate cell densities. Results: The fluid flow pattern found in the most promising modification (#2) was altered by increasing the impeller blade angle and lowering the off-bottom clearance. As a result, the maximum required specific power input was reduced by a factor of 2.2–4.6, depending on the microcarrier concentration, and peak cell densities were 3.4-times higher than in the standard version. Conclusion: The peak cell number of nearly 1.1 × 109 cells (expansion factor = 35), which was achieved in our low-serum cultivations, indicates an improvement in the redesigned UniVessel® SU configuration f...

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改良和鉴定搅拌一次性生物反应器，以改善台式规模的人间充质干细胞的扩增

背景:为了改善人骨髓间充质干细胞的培养条件，我们利用计算流体动力学的结果重新设计了市售的UniVessel®SU生物反应器。目标是产生≥1 × 109个细胞，扩增因子≥30。筛选研究表明，微载体固体组分至少需要0.3%才能达到适当的细胞密度。结果:最理想的改型(#2)是通过增加叶轮叶片角度和降低离底间隙来改变流体的流态。因此，根据微载流子浓度的不同，所需的最大比功率输入降低了2.2-4.6倍，峰值电池密度比标准版本高3.4倍。结论:在我们的低血清培养中，达到了近1.1 × 109个细胞(扩增因子= 35)的峰值细胞数，这表明重新设计的UniVessel®SU配置的改进。

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Pharmaceutical bioprocessing

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