Mercille S, Johnson M, Lanthier S, Kamen A A, Massie B
Institut de Recherche en Biotechnologie, Conseil National de Recherches du Canada, 6100 Avenue Royalmount, Montréal, PQ, Canada, H4P 2R2.
Biotechnol Bioeng. 2000 Feb 20;67(4):435-50. doi: 10.1002/(sici)1097-0290(20000220)67:4<435::aid-bit7>3.0.co;2-y.
One of the key parameters in perfusion culture is the rate of medium replacement (D). Intensifying D results in enhanced provision of nutrients, which can lead to an increase in the viable cell density (X(v)). The daily MAb production of hybridoma cells can thus be increased proportionally without modifying the bioreactor scale, provided that both viable cell yield per perfusion rate (Y(Xv/D)) and specific MAb productivity (q(MAb)) remain constant at higher D. To identify factors prone to limit productivity in perfusion, a detailed kinetic analysis was carried out on a series of cultures operated within a D range of 0.48/4.34 vvd (volumes of medium/reactor volume/day) in two different suspension-based systems. In the Celligen/vortex-flow filter system, significant reductions in Y(Xv/D) and q(MAb) resulting from the use of gas sparging were observed at D > 1.57 vvd (X(v) > 15 x 10(6) cells/mL). Through glucose supplementation, we have shown that the decrease in Y(Xv/D) encountered in presence of sparging was not resulting from increased cellular destruction or reduced cell growth, but rather from glucose limitation. Thus, increases in hydrodynamic shear stress imparted to the culture via intensification of gas sparging resulted in a gradual increase in specific glucose consumption (q(glc)) and lactate production rates (q(lac)), while no variations were observed in glutamine-consumption rates. As a result, while glutamine was the sole limiting-nutrient under non-sparging conditions, both glutamine and glucose became limiting under sparging conditions. Although a reduction in q(MAb) was observed at high-sparging rates, inhibition of MAb synthesis did not result from direct impact of bubbles, but was rather associated with elevated lactate levels (25-30 mM), resulting from shear stress-induced increases in q(lac), q(glc), and Y(lac/glc). Deleterious effects of sparging on Y(Xv/D) and q(MAb) encountered in the Celligen/vortex-flow filter system were eliminated in the sparging-free low-shear environment of the Chemap-HRI/ultrasonic filter system, allowing for the maintenance of up to 37 x 10(6) viable cells/mL. A strategy aimed at reducing requirements for sparging in large-scale perfusion cultures by way of a reduction in the oxygen demand using cellular engineering is discussed.
灌注培养的关键参数之一是培养基更换速率(D)。提高D会增加营养物质的供应,这可能导致活细胞密度(X(v))增加。因此,在不改变生物反应器规模的情况下,杂交瘤细胞的每日单克隆抗体产量可以按比例增加,前提是在较高的D下,每灌注速率的活细胞产量(Y(Xv/D))和单克隆抗体比生产率(q(MAb))保持恒定。为了确定灌注中容易限制生产率的因素,在两种不同的基于悬浮培养的系统中,对一系列在0.48/4.34 vvd(培养基体积/反应器体积/天)的D范围内运行的培养物进行了详细的动力学分析。在Celligen/涡流过滤系统中,当D > 1.57 vvd(X(v) > 15×10⁶个细胞/mL)时,观察到由于气体鼓泡导致Y(Xv/D)和q(MAb)显著降低。通过补充葡萄糖,我们表明在鼓泡存在的情况下遇到的Y(Xv/D)下降不是由于细胞破坏增加或细胞生长减少,而是由于葡萄糖限制。因此,通过强化气体鼓泡施加给培养物的流体动力剪切应力增加导致比葡萄糖消耗(q(glc))和乳酸产生速率(q(lac))逐渐增加,而谷氨酰胺消耗速率没有变化。结果,虽然在无鼓泡条件下谷氨酰胺是唯一的限制营养物质,但在鼓泡条件下谷氨酰胺和葡萄糖都成为限制因素。尽管在高鼓泡速率下观察到q(MAb)降低,但单克隆抗体合成的抑制不是由气泡的直接影响导致的,而是与乳酸水平升高(25 - 30 mM)相关,这是由剪切应力诱导的q(lac)、q(glc)和Y(lac/glc)增加引起的。在Chemap - HRI/超声过滤系统的无鼓泡低剪切环境中,消除了Celligen/涡流过滤系统中鼓泡对Y(Xv/D)和q(MAb)的有害影响,允许维持高达37×10⁶个活细胞/mL。讨论了一种通过细胞工程降低氧气需求来减少大规模灌注培养中鼓泡需求的策略。
