Rational development of fed-batch mammalian cell culture processes

补料分批哺乳动物细胞培养工艺的合理开发

• 批准号: RGPIN-2016-06407
• 负责人: Henry, Olivier
• 金额: $ 2.04万
• 依托单位: École Polytechnique de Montréal
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2020
• 资助国家: 加拿大
• 起止时间: 2020-01-01 至 2021-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=710186
• 关键词: Rational; development; fed; batch; mammalian

Mammalian cell culture remains the dominant expression system for the manufacturing of recombinant proteins for clinical applications. With several hundreds of protein products currently in clinical trials and with the anticipated emergence of several blockbuster biosimilars, the biotherapeutics market is expected to grow exponentially within the next decade. For the majority of these novel bioproducts, the capacity to mass produce them in a cost-efficient manner will be a critical factor for their successful translation to the clinic and market. The central goal of this NSERC Discovery Research Program is to devise innovative strategies that will enable the rapid development of robust and cost-effective cell culture-based manufacturing processes. To better cope with the inherent complexity of mammalian cell cultures, the research will be conducted following a multi-scale system's approach integrating information at the cellular and process levels. More specifically, the research program will aim to i) conduct comprehensive metabolic characterization of mammalian cells under relevant process conditions in order to guide and streamline optimization efforts ii) develop reliable mathematical models linking process conditions and cell culture state in order to simulate and predict process performance and iii) design and implement efficient model-based dynamic fed-batch strategies ensuring high product yield and consistency. The methodology will be based on advanced and emerging analytical methods, including the use of mass spectrometry analysis and isotopic tracers for conducting metabolic studies and surface plasmon resonance (SPR) for rapid at-line assessment of product bioactivity. The research will primarily target an industrially relevant application, the production of monoclonal antibodies by Chinese Hamster Ovary (CHO) cells, as these cells are the main workhorse of the biopharmaceutical industry. The research will also pursue the development of cell culture processes involving mammalian cells that have been engineered to possess an improved metabolic efficiency. The novelty of the research program lies not only in its anticipated outcomes, but also in the innovative application of a multi-scale systems approach combining cellular and process engineering strategies for conducting rational process development and generating new knowledge. This research is expected to bring a significant contribution to the development and manufacturing of biotherapeutics, an area of considerable economic importance and having a direct impact on the health and welfare of Canadian citizens. By addressing the needs for improved and efficient bioprocesses, these research efforts can help to reduce the cost and time in getting recombinant products to the clinic and market and will thus ultimately benefit both patients and industry.

哺乳动物细胞培养仍然是生产临床应用重组蛋白的主要表达系统。目前有数百种蛋白质产品正在进行临床试验，并且预计将出现几种重磅生物仿制药，生物治疗市场预计将在未来十年内呈指数级增长。对于大多数新型生物产品而言，以经济高效的方式大规模生产它们的能力将是其成功转化为临床和市场的关键因素。 NSERC 发现研究计划的中心目标是制定创新策略，以实现稳健且经济高效的基于细胞培养的制造工艺的快速开发。为了更好地应对哺乳动物细胞培养物固有的复杂性，该研究将按照多尺度系统的方法进行，整合细胞和过程水平的信息。更具体地说，该研究计划的目标是 i) 在相关过程条件下对哺乳动物细胞进行全面的代谢表征，以指导和简化优化工作 ii) 开发连接过程条件和细胞培养状态的可靠数学模型，以模拟和预测过程iii) 设计和实施高效的基于模型的动态补料策略，确保高产品产量和一致性。 该方法将基于先进和新兴的分析方法，包括使用质谱分析和同位素示踪剂进行代谢研究，以及使用表面等离子共振（SPR）来快速在线评估产品生物活性。该研究将主要针对工业相关应用，即通过中国仓鼠卵巢 (CHO) 细胞生产单克隆抗体，因为这些细胞是生物制药行业的主要主力。该研究还将致力于开发涉及哺乳动物细胞的细胞培养工艺，这些细胞经过改造后具有更高的代谢效率。 该研究计划的新颖性不仅在于其预期结果，还在于结合细胞和过程工程策略的多尺度系统方法的创新应用，以进行合理的过程开发并产生新知识。这项研究预计将为生物治疗药物的开发和制造做出重大贡献，该领域具有相当大的经济重要性，并对加拿大公民的健康和福利产生直接影响。通过满足改进和高效生物工艺的需求，这些研究工作可以帮助减少将重组产品推向临床和市场的成本和时间，从而最终使患者和行业受益。