Henry Olivier, Dormond Edwige, Perrier Michel, Kamen Amine
Ecole Polytechnique de Montréal, Montréal, Québec, Canada.
Biotechnol Bioeng. 2004 Jun 30;86(7):765-74. doi: 10.1002/bit.20074.
One of the major limitations in the production of adenoviral vectors is the reduction in cell-specific productivity observed for increasing cell density at infection in batch cultures. This observation strongly suggests some nutrient depletion and/or metabolite inhibition in the media. These limitations have been partially overcome through other feeding strategies, such as fed-batch and sequential batch operations. To improve these results, we evaluated perfusion as a strategy to increase the volumetric productivity of HEK-293 cell cultures, by allowing productive infection at higher cell densities. An acoustic cell separator was employed in consideration of the increased shear sensitivity of the cells during the infection phase. The effects of perfusion rate and cell density at infection on the production of a recombinant adenovirus expressing the GFP were investigated. The perfusion mode allowed successful infection at cell densities in the range of 2.4-3 x 10(6) cell/mL, while maintaining a similar cell specific productivity (17,900 +/- 2400 VP/cell) to that of a batch infected at a low cell density (5 x 10(5) cell/mL). The highest virus concentrations (4.1 +/- 0.6 x 10(10) VP/mL) were attained for a feed rate of 2 vol/d and constituted a fivefold increase compared to a batch with medium replacement. Rapid assessment of the infection status was achieved through the use of on-line monitoring of respiration, fluorescence, and biovolume. Analysis of the kinetics of nutrient consumption and metabolite production revealed that a reduction in specific productivity is correlated with reduced metabolic activity.
腺病毒载体生产中的一个主要限制是,在分批培养中,随着感染时细胞密度的增加,细胞特异性生产力会降低。这一观察结果强烈表明培养基中存在一些营养物质耗尽和/或代谢物抑制的情况。通过其他补料策略,如补料分批培养和连续分批操作,这些限制已得到部分克服。为了改善这些结果,我们评估了灌注作为一种提高HEK - 293细胞培养体积生产力的策略,通过允许在更高的细胞密度下进行有效感染。考虑到感染阶段细胞对剪切力的敏感性增加,采用了一种声学细胞分离器。研究了灌注速率和感染时的细胞密度对表达绿色荧光蛋白的重组腺病毒生产的影响。灌注模式允许在2.4 - 3×10⁶个细胞/毫升的细胞密度下成功感染,同时保持与低细胞密度(5×10⁵个细胞/毫升)分批感染相似的细胞特异性生产力(17,900±2400个病毒粒子/细胞)。对于2体积/天的进料速率,获得了最高的病毒浓度(4.1±0.6×10¹⁰个病毒粒子/毫升),与进行培养基更换的分批培养相比增加了五倍。通过在线监测呼吸、荧光和生物量实现了对感染状态的快速评估。对营养物质消耗和代谢物产生动力学的分析表明,特异性生产力的降低与代谢活性的降低相关。
