Eric Wynne, Junghyo Yoon, Dohyun Park, Mingyang Cui, Caitlin Morris, Jaeweon Lee, Zhao Wang, Seongkyu Yoon, Jongyoon Han
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引用次数: 0
摘要
在现代生物处理过程中,细胞培养基是最重要的成本驱动因素之一,但培养基中的营养物质和其他关键因素往往没有得到充分利用。随着人们对降低生物处理成本的重新重视,减少细胞培养基的总体使用量备受关注。在这项工作中,我们引入了一种基于离子浓度极化(ICP)工艺的中尺度微流体分离装置,通过去除细胞培养物中已知会抑制细胞生长的关键废品,再生废培养基以供再利用。我们证明,多达 75% 的废培养基可以再生和重复使用,而不会影响细胞活力。对抗体生产过程中所消耗材料的详细分析表明,通过再生和循环利用培养基,可以将水处理过程的质量强度提高 33%。鉴于 ICP 分离系统已经扩大到支持大容量处理,因此将这项技术应用于生产规模的生物反应器(如 50 升 CHO 细胞灌流培养)是可行的,从而降低了整体运营成本和用水量。
Regeneration of Spent Culture Media for Sustainable and Continuous mAb Production via Ion Concentration Polarization.
In modern bioprocessing, cell culture media is one of the most significant cost drivers, yet the nutrients and other critical factors in the media are often not fully utilized. With the renewed emphasis on reducing the cost of bioprocessing, there is much interest in reducing the overall use of cell culture media. In this work, we introduce a mesoscale microfluidic separation device based on the ion concentration polarization (ICP) process to regenerate the spent media for reuse by removing critical waste products from the cell culture that are known to inhibit the growth of the cells. We demonstrated that up to 75% of spent culture media can be regenerated and reused without affecting the cell viability. A detailed analysis of the materials consumed during antibody production indicated that one could improve the water process mass intensity by up to 33% by regenerating and recycling the media. Given that ICP separation systems have already been scaled up to support large-volume processing, it would be feasible to deploy this technology for manufacturing scale bioreactors (e.g., 50 L perfusion culture of CHO cells), reducing the overall operation cost and water use.
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