CHO工程细胞 (11G-S) 悬浮培养的无血清培养基的设计

以悬浮适应的表达重组尿激酶原 (Pro-urokinase,pro-UK) CHO工程细胞系11G-S为对象,采用Plackett-Burman实验设计及响应面分析法,设计支持CHO工程细胞 (11G-S) 悬浮生长的无血清培养基。以细胞密度为评价指标,在单因素实验的基础上采用Plackett-Burman实验设计对影响细胞生长的培养基添加成分进行考察,确定了3种对细胞生长明显促进作用的培养基添加成分：胰岛素、转铁蛋白及腐胺。继而利用响应面法分析了这3种添加成分的最佳水平范围,设计了一种适用于CHO工程细胞 (11G-S) 悬浮培养的无血清培养基SFM-CHO-S。11G-S细胞在SFM-CHO-S批次悬浮培养的细胞最大生长密度达到4.12×106 cells/mL,pro-UK的最大累积活性达到5 614 IU/mL,培养效果优于商品化的同类无血清培养基。     

类弹性蛋白多肽的从头设计、非色谱纯化及盐效应

近年来,因病毒侵害人类每年都要蒙受巨大的经济损失和社会损失。犬肾细胞MDCK以其具有的培养容易、增殖快、流感病毒感染效率高等特点,成为适用于流感病毒疫苗生产的重要细胞系之一。以MDCK细胞为研究对象,在自制无血清培养基中成功实现了MDCK细胞从有血清培养到无血清培养的驯化;并通过单细胞悬浮培养驯化过程实现了MDCK细胞的无血清单细胞悬浮培养,获得了适于无血清单细胞悬浮生长的ssf-MDCK细胞株,无血清单细胞悬浮批培养最大活细胞密度可达3.81×106 cells/mL,最大比生长速率可达0.056 h?     

CHO工程细胞无血清悬浮分批培养的生长代谢特征及动力学模型

以悬浮适应的表达尿激酶原CHO工程细胞为研究对象,在100mL的摇瓶中进行无血清悬浮培养,以细胞密度、细胞活力、Pro-UK活性、葡萄糖比消耗速率(qglc)、乳酸比生产速率(qlac)、乳酸对葡萄糖的得率系数(Ylac/glc)为观察指标,同时以细胞有血清悬浮培养作为参照,考察CHO工程细胞无血清悬浮培养生长和代谢特征。观察结果表明,CHO工程细胞在无血清及有血清悬浮培养条件下表现为大致相似的细胞生长和代谢特征。在此基础上,依据实际检测的数据,应用MATLAB软件对细胞对数生长期的细胞生长、乳酸生成及葡萄糖消耗的模型参数进行非线性规划,获得全局性收敛的最优参数估计值,建立了细胞在无血清培养条件下的生长及代谢动力学模型。     

纤维素多孔微载体的制备及其用于动物细胞培养

将纤维素铜氨溶液喷洒至-40℃的硅油：正己烷=1：4的冷冻液中形成含冰晶的微球,用-30℃、40%的H₂SO₄再生纤维素,并用EDAE盐酸盐修饰其表面,制成适合动物细胞培养的纤维素多孔微载体。利用该微载体培养能分泌尿激酶原(Pro-UK)的重组CHO细胞,在100mL搅拌瓶中换液培养25d,细胞最高密度为6.3×10⁶/mL,尿激酶原最高活性为2325IU/mL,共获28.7mg产品。之后转入1000mL搅拌瓶中培养,可观察到细胞可从种子微载体中自动转移到新微载体中生长繁殖直至所有微载体中都长有细胞。在25d二级培养中,细胞最高密度为7.3×10⁶/mL,尿激酶原最高活性为3108IU/mL,共获含353mg尿激酶原的上清13.7L。在培养后期换用无血清培养基培养,细胞生长及蛋白表达水平正常。     

用填充床生物反应器大规模培养表达重组人红细胞生成素的细胞株

目的：用填充床生物反应器培养表达重组人红细胞生成素的工程细胞株C2W,使其达到高密度高表达。方法：将工程细胞株用含5％小牛血清的DF培养基复苏放大培养,当细胞达到10^9时,接种到5L生物反应器中,先用含血清培养基生长培养,再换为无血清培养基表达培养;在整个培养过程中,采用流加方式连续培养,每日采样测定培养上清中葡萄糖浓度,隔日测定细胞的表达水平。结果：接种量约为10^9细胞;细胞罐培养57d,包括含血清生长培养6d,无血清表达培养51d：重组人红细胞生成素平均表达水平为5636U／mL,最高时达7880U／mL;收集无血清培养上清476L,平均每日灌流量8.3L,最高时达12L／日。结论：在适当的条件下,利用填充床生物反应器可使工程细胞株的培养达到长时间、高表达。     

薰衣草细胞悬浮培养体系的优化

采用正交设计方法对影响薰衣草悬浮细胞生长的因素进行了优化研究,筛选了最有利于薰衣草悬浮细胞生长的培养条件:含有0.025mg/L2,4-D、0.5mg/L6-BA、40g/L蔗糖的B5培养基和120r/min的转速,在此条件下培养15天,悬浮活细胞密度可达到4.4×105个/ml;经过3个月的培养,悬浮细胞的分化率可达到90%以上。通过分析薰衣草细胞对残糖的消耗规律,探讨了蔗糖浓度影响活细胞密度的原因。     

血清浓度及溶氧对培养rCHO细胞生产尿激酶原的影响

在30L搅拌式反应器中用多孔微载体培养分泌尿激酶原的DNA重组中国仓鼠卵巢细胞(rCHO),研究了血清浓度及溶氧对细胞生长和表达的影响.结果表明,在2×105/ml低密度接种条件下,使用低(无)血清培养基会延长细胞生长延滞期并降低比生长速率,而细胞密度大于106/ml时,血清浓度对细胞生长和产物表达的影响没有显著差别.溶氧(DO)维持在20%～45%时,对细胞表达产物和葡萄糖代谢无明显影响,但溶氧降至7%～9%时,细胞表达水平明显降低,葡萄糖代谢转化为乳酸的比例上升.     

牛肾细胞在两种不同载体中培养效果的比较

目的通过牛肾细胞在两种不同载体中培养效果的比较,为牛肾细胞在细胞工厂中规模化生产提供真实的、有力的支持。方法不同代次牛肾细胞在两种载体中经过相同培养条件进行培养。结果实验中原代牛肾细胞在细胞工厂接种密度为5.5×104/cm2左右,在15 L转瓶接种密度为9.0×104/cm2左右。一代牛肾细胞在细胞工厂接种密度为6.5×104/cm2左右,在15 L转瓶接种密度为10×104/cm2左右。二代牛肾细胞在细胞工厂接种密度为7.0×104/cm2左右,在15 L转瓶接种密度为14×104/cm2左右。两种载体中牛肾细胞生长状况均能达到培养要求。结论细胞工厂能在有限的空间内利用最大限度的培养表面培养牛肾细胞,不仅节约了传代前的细胞用量,而且提高了培养后的细胞产量。     

Mixture与响应面法结合开发BHK-21细胞无血清悬浮培养基

采用Mixture与响应面实验设计相结合的方法开发BHK-21细胞无血清悬浮培养基。在实验室已知配方的6种培养基A-F的基础上,通过Mixture实验筛选出BHK-21细胞无血清培养基的最优组合为A∶B∶C∶D∶E∶F=0∶0∶11∶0∶9∶0。利用响应面法针对培养基中的几种关键组分进行浓度优化,确定谷氨酰胺、酪氨酸、牛血清白蛋白和钙离子的最优浓度分别为3 mmol/L、2.5 g/L、0 g/L和0 mmol/L。该无血清悬浮培养基能很好地支持BHK细胞悬浮生长,培养时细胞最大活细胞密度可达140.21×105个/m L,比商业培养基提高了1.95倍。采用Mixture试验设计和响应面分析法能够在较短的时间内开发出适合BHK-21细胞生长的无血清悬浮培养基,为采用BHK-21细胞大规模工业化生产口蹄疫疫苗奠定了基础。     

固相化HEK细胞在无血清培养基中高效表达重组人活性蛋白C

研究固相化HEK工程细胞的培养和产生rhAPC的水平。先将HEK细胞由贴壁适应为无血清悬浮培养,再用海藻酸钙固定,并在无血清培养基中悬浮培养(最高约为27mg/L)。固相细胞动态培养的表达水平高于细胞静态悬浮培养的表达水平(最高约为50mg/L)。固相细胞动态培养可实现细胞的高密度培养,得到较高的表达水平。     

Process intensification in fed-batch production bioreactors using non-perfusion seed cultures

ABSTRACT

Although process intensification by continuous operation has been successfully applied in the chemical industry, the biopharmaceutical industry primarily uses fed-batch, rather than continuous or perfusion methods, to produce stable monoclonal antibodies (mAbs) from Chinese hamster ovary (CHO) cells. Conventional fed-batch bioreactors may start with an inoculation viable cell density (VCD) of ~0.5 × 10⁶ cells/mL. Increasing the inoculation VCD in the fed-batch production bioreactor (referred to as N stage bioreactor) to 2–10 × 10⁶ cells/mL by introducing perfusion operation or process intensification at the seed step (N-1 step) prior to the production bioreactor has recently been used because it increases manufacturing output by shortening cell culture production duration. In this study, we report that increasing the inoculation VCD significantly improved the final titer in fed-batch production within the same 14-day duration for 3 mAbs produced by 3 CHO GS cell lines. We also report that other non-perfusion methods at the N-1 step using either fed batch or batch mode with enriched culture medium can similarly achieve high N-1 final VCD of 22–34 × 10⁶ cells/mL. These non-perfusion N-1 seeds supported inoculation of subsequent production fed-batch production bioreactors at increased inoculation VCD of 3–6 × 10⁶ cells/mL, where these achieved titer and product quality attributes comparable to those inoculated using the perfusion N-1 seeds demonstrated in both 5-L bioreactors, as well as scaled up to 500-L and 1000-L N-stage bioreactors. To operate the N-1 step using batch mode, enrichment of the basal medium was critical at both the N-1 and subsequent intensified fed-batch production steps. The non-perfusion N-1 methodologies reported here are much simpler alternatives in operation for process development, process characterization, and large-scale commercial manufacturing compared to perfusion N-1 seeds that require perfusion equipment, as well as preparation and storage vessels to accommodate large volumes of perfusion media. Although only 3 stable mAbs produced by CHO cell cultures are used in this study, the basic principles of the non-perfusion N-1 seed strategies for shortening seed train and production culture duration or improving titer should be applicable to other protein production by different mammalian cells and other hosts at any scale biologics facilities.     

Process development for an inducible rituximab-expressing Chinese hamster ovary cell line

Inducible mammalian expression systems are becoming increasingly available and are not only useful for the production of cytotoxic/cytostatic products, but also confer the unique ability to uncouple the growth and production phases. In this work, we have specifically investigated how the cell culture state at the time of induction influences the cumate-inducible expression of recombinant rituximab by a GS-CHO cell line. To this end, cells grown in batch and fed-batch cultures were induced at increasing cell densities (1 to 10 × 10 ⁶ cells/mL). In batch, the cell specific productivity and the product yield were found to reduce with increasing cell density at induction. A dynamic feeding strategy using a concentrated nutrient solution applied prior and postinduction allowed to significantly increase the integral of viable cells and led to a 3-fold increase in the volumetric productivity (1.2 g/L). The highest product yields were achieved for intermediate cell densities at induction, as cultures induced during the late exponential phase (10 × 10 ⁶ cells/mL) were associated with a shortened production phase. The final glycosylation patterns remained however similar, irrespective of the cell density at induction. The kinetics of growth and production in a 2 L bioreactor were largely comparable to shake flasks for a similar cell density at induction. The degree of galactosylation was found to decrease over time, but the final glycan distribution at harvest was consistent to that of the shake flasks cultures. Taken together, our results provide useful insights for the rational development of fed-batch cell culture processes involving inducible CHO cells. © 2018 American Institute of Chemical Engineers Biotechnol. Prog., 35: e2742, 2019     

High viable cell concentration fed-batch cultures of hybridoma cells through on-line nutrient feeding

A hybridoma cell line was cultivated in fed-batch cultures using a low-protein, serum-free medium. On-line oxygen uptake rate (OUR) measurement was used to adjust the nutrient feeding rate based on glucose consumption, which was estimated on-line using the stoichiometric relations between glucose and oxygen consumption. Through on-line control of the nutrient feeding rate, not only sufficients were supplied for cell growth and antibody production, but also the concentrations of glucose and other important nutrients such as amino acids were maintained at low levels during the cell growth phase. During the cultivation, cell metabolism changed from high lactate production and low oxygen consumption to low lactate production and high oxygen consumption. As a result the accumulation of lactate was reduced and the growth phase was extended. In comparison with the batch cultures, in which cells reached a concentration of approximately 2 x 10(6) cells/mL, a very high concentration of 1.36 x 10(7) cells/mL with a high cell viability (>90%) was achieved in the fed-batch culture. By considering the consumption of glucose and amino acids, as well as the production of cell mass, metabolites, and antibodies, a well-closed material balance was established. Our results demonstrate the value of coupling on-line OUR measurement and the stoichiometric realations for dynamic nutrient feeding in high cell concentration fed batch cultures. (c) 1995 John Wiley & Sons, Inc.     

批次和流加培养中国仓鼠卵巢工程细胞的细胞周期相关基因转录谱分析

以表达人重组尿激酶原中国仓鼠卵巢 (CHO) 工程细胞系11G-S为研究对象,运用基因芯片技术比较了CHO工程细胞在批次及流加培养不同生长阶段基因表达水平的差异,在此基础上采用Genmapp软件,同时结合已知的细胞周期信号通路图,着重分析了批次及流加培养CHO工程细胞的细胞周期调控基因转录谱差异。在基因芯片涉及的19 191个目标基因中,批次和流加培养不同生长阶段CHO工程细胞的下调表达的基因数量多于上调表达基因数目;两种培养模式下的基因差异表达有着明显的不同,尤其是在细胞生长的衰退期,流加培养CHO工程细胞中下调表达的基因数量明显多于批次培养。有关调控细胞周期关键基因的转录谱分析表明,CHO工程细胞主要是通过下调表达CDKs、Cyclin及CKI家族中的Cdk6、Cdk2、Cdc2a、Ccne1、Ccne2基因及上调表达Smad4基因,来达到调控细胞增殖及维持自身活力的目的。     

Alteration of mammalian cell metabolism by dynamic nutrient feeding

The metabolism of hybridoma cells was controlled to reduce metabolic formation in fed-batch cultures by dynamically feeding a salt-free nutrient concentrate. For this purpose, on-line oxygen uptake rate (OUR) measurement was used to estimate the metabolic demand of hybridoma cells and to determine the feeding rate of a concentrated solution of salt-free DMEM/F12 medium supplemented with other medium components. The ratios among glucose, glutamine and other medium components in the feeding nutrient concentrate were adjusted stoichiometrically to provide balanced nutrient conditions for cell growth. Through on-line control of the feeding rate of the nutrient concentrate, both glucose and glutamine concentrations were maintained at low levels of 0.5 and 0.2 mM respectively during the growth stage. The concentrations of the other essential amino acids were also maintained without large fluctuations. The cell metabolism was altered from that observed in batch cultures resulting in a significant reduction of lactate, ammonia and alanine production. Compared to a previously reported fed-batch culture in which only glucose was maintained at a low level and only a reduced lactate production was observed, this culture has also reduced the production of other metabolites, such as ammonium and alanine. As a result, a high viable cell concentration of more than 1.0 × 10⁷ cells/mL was achieved and sustained over an extended period. The results demonstrate an efficient nutrient feeding strategy for controlling cell metabolism to achieve and sustain a high viable cell concentration in fed-batch mammalian cell cultures in order to enhance the productivity. This revised version was published online in July 2006 with corrections to the Cover Date.     

Large-scale, high-density freezing of hybridomas and its application to high-density culture

Large-scale, high-density freezing of hybridomas was studied to apply frozen cells to start high-density culture. We showed here that hybridomas can be frozen at 1.5 x 10(8) cells/mL, without decrement in viability and proliferating activity. Blood transporting bags were used for large-scale freezing to store 25 mL of cell suspension with a cell density, 1.5 x 10(8)/mL. The number of cells stored in a bag (3.0 x 10(9) cells) was enough to start a high-density culture at a 10 times higher cell density (6.0 x 10(6) cells/mL) than normal inoculation, and the cells proliferated to 10(7) cells/mL within 2 days. These results indicate that the large-scale freezing method is useful for large-scale culture of mammalian cells.     

Fed-batch culture optimization of a growth-associated hybridoma cell line in chemically defined protein-free media

An investigation was made to study the processes of fed-batch cultures of a hybridoma cell line in chemically defined protein-free media. First of all, a strong growth-associated pattern was correlated between the production of MAb and growth of cells through the kinetic studies of batch cultures, suggesting the potential effectiveness of extending the duration of exponential growth in the improvement of MAb titers. Second, compositions of amino acids in the feeding solution were balanced stepwisely according to their stoichiometrical correlations with glucose uptake in batch and fed-batch cultures. Moreover, a limiting factor screening revealed the constitutive nature of Ca²⁺ and Mg²⁺ for cell growth, and the importance of their feeding in fed-batch cultures. Finally, a fed-batch process was executed with a glucose uptake coupled feeding of balanced amino acids together with groups of nutrients and a feeding of CaCl₂ and MgCl₂ concentrate. The duration of exponential cell growth was extended from 70 h in batch culture and 98 h in fed-batch culture without Ca²⁺/Mg²⁺ feeding to 117 h with Ca²⁺/Mg²⁺ feeding. As a result of the prolonged exponential cell growth, the viable and total cell densities reached 7.04 × 10⁶ and 9.12 × 10⁶ cells ml⁻¹, respectively. The maximal MAb concentration achieved was increased to approximately eight times of that in serum supplemented batch culture.