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使用电容探头进行生物制造的 N-1 灌注平台开发

N-1 Perfusion Platform Development Using a Capacitance Probe for Biomanufacturing.

作者信息

Rittershaus Emily S C, Rehmann Matthew S, Xu Jianlin, He Qin, Hill Charles, Swanberg Jeffrey, Borys Michael C, Li Zheng-Jian, Khetan Anurag

机构信息

Biologics Development, Global Product Development and Supply, Bristol Myers Squibb Company, Devens, MA 01434, USA.

出版信息

Bioengineering (Basel). 2022 Mar 22;9(4):128. doi: 10.3390/bioengineering9040128.

DOI:10.3390/bioengineering9040128
PMID:35447688
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9029935/
Abstract

Fed-batch process intensification with a significantly shorter culture duration or higher titer for monoclonal antibody (mAb) production by Chinese hamster ovary (CHO) cells can be achieved by implementing perfusion operation at the N-1 stage for biomanufacturing. N-1 perfusion seed with much higher final viable cell density (VCD) than a conventional N-1 batch seed can be used to significantly increase the inoculation VCD for the subsequent fed-batch production (referred as N stage), which results in a shorter cell growth phase, higher peak VCD, or higher titer. In this report, we incorporated a process analytical technology (PAT) tool into our N-1 perfusion platform, using an in-line capacitance probe to automatically adjust the perfusion rate based on real-time VCD measurements. The capacitance measurements correlated linearly with the offline VCD at all cell densities tested (i.e., up to 130 × 10 cells/mL). Online control of the perfusion rate via the cell-specific perfusion rate (CSPR) decreased media usage by approximately 25% when compared with a platform volume-specific perfusion rate approach and did not lead to any detrimental effects on cell growth. This PAT tool was applied to six mAbs, and a platform CSPR of 0.04 nL/cell/day was selected, which enabled rapid growth and maintenance of high viabilities for four of six cell lines. In addition, small-scale capacitance data were used in the scaling-up of N-1 perfusion processes in the pilot plant and in the GMP manufacturing suite. Implementing a platform approach based on capacitance measurements to control perfusion rates led to efficient process development of perfusion N-1 for supporting high-density CHO cell cultures for the fed-batch process intensification.

摘要

通过在中国仓鼠卵巢(CHO)细胞生产单克隆抗体(mAb)的过程中,在N-1阶段实施灌注操作,可以实现补料分批过程强化,显著缩短培养时间或提高滴度。与传统的N-1批次种子相比,具有更高最终活细胞密度(VCD)的N-1灌注种子可用于显著提高后续补料分批生产(称为N阶段)的接种VCD,这导致细胞生长阶段更短、峰值VCD更高或滴度更高。在本报告中,我们将过程分析技术(PAT)工具纳入我们的N-1灌注平台,使用在线电容探头根据实时VCD测量自动调整灌注速率。在所有测试的细胞密度(即高达130×10个细胞/mL)下,电容测量值与离线VCD呈线性相关。与平台体积特异性灌注速率方法相比,通过细胞特异性灌注速率(CSPR)在线控制灌注速率可使培养基用量减少约25%,且不会对细胞生长产生任何有害影响。该PAT工具应用于六种单克隆抗体,并选择了0.04 nL/细胞/天的平台CSPR,这使得六种细胞系中的四种能够快速生长并维持高活力。此外,小规模电容数据用于中试工厂和GMP生产套件中N-1灌注过程的放大。实施基于电容测量的平台方法来控制灌注速率,导致灌注N-1的高效工艺开发,以支持用于补料分批过程强化的高密度CHO细胞培养。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/d6b1/9029935/e60993ed7785/bioengineering-09-00128-g007.jpg
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