Development of bioreactor scale-down model using orthogonal projections to latent structures method and CO2 supplementation

IF 2.5 3区生物学 Q3 BIOTECHNOLOGY & APPLIED MICROBIOLOGY Biotechnology Progress Pub Date : 2024-01-30 DOI:10.1002/btpr.3423

Jinxin Gao, Laurie B. Hazeltine, Neal Stroud, Ning Liu, Yao-ming Huang

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Abstract

Scale-down model qualification is an important step for developing a large-scale cell culture process to enhance process understanding and support process characterization studies. Traditionally, only harvest data are used to show consistency between small-scale and large-scale bioreactor performance, allowing attributes that are dynamic over the cell culture period to be overlooked. A novel statistical method, orthogonal projections to latent structures (OPLS) analysis, can be utilized to compare time-course cell culture data across scales. Here we describe an example where OPLS is used to identify gaps between small-scale and large-scale bioreactor performances. In this case, differences in the partial pressure of carbon dioxide (pCO₂) and lactate profiles were observed between small- and large-scale bioreactors, which were linked to differences in the product-quality attributes fragments and galactosylation. An improved small-scale model was developed, leading to improved consistency in the process performance and product qualities across scales and qualification of the scale-down model for regulatory submissions. This new statistical approach can provide valuable insights into process understanding and process scale-up.

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利用正交投影潜伏结构法和二氧化碳补充法开发生物反应器缩小模型。

缩小模型鉴定是开发大规模细胞培养工艺的重要步骤，可加深对工艺的理解并支持工艺特征研究。传统上，只有收获数据才能显示小规模和大规模生物反应器性能之间的一致性，从而忽略了细胞培养期间的动态属性。一种新颖的统计方法--潜在结构正交投影（OPLS）分析，可用于比较不同规模的时间历程细胞培养数据。在这里，我们介绍一个利用 OPLS 找出小规模和大规模生物反应器性能差距的例子。在这个例子中，我们观察到小型和大型生物反应器之间二氧化碳分压（pCO2）和乳酸盐曲线的差异，这与产品质量属性片段和半乳糖基化的差异有关。改进后的小规模模型得以开发，从而提高了不同规模生物反应器的工艺性能和产品质量的一致性，并使缩小模型符合监管要求。这一新的统计方法可为工艺理解和工艺放大提供有价值的见解。

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来源期刊

Biotechnology Progress 工程技术-生物工程与应用微生物

CiteScore

6.50

自引率

3.40%

发文量

审稿时长

4 months

期刊介绍： Biotechnology Progress , an official, bimonthly publication of the American Institute of Chemical Engineers and its technological community, the Society for Biological Engineering, features peer-reviewed research articles, reviews, and descriptions of emerging techniques for the development and design of new processes, products, and devices for the biotechnology, biopharmaceutical and bioprocess industries. Widespread interest includes application of biological and engineering principles in fields such as applied cellular physiology and metabolic engineering, biocatalysis and bioreactor design, bioseparations and downstream processing, cell culture and tissue engineering, biosensors and process control, bioinformatics and systems biology, biomaterials and artificial organs, stem cell biology and genetics, and plant biology and food science. Manuscripts concerning the design of related processes, products, or devices are also encouraged. Four types of manuscripts are printed in the Journal: Research Papers, Topical or Review Papers, Letters to the Editor, and R & D Notes.

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