Cell growth optimization in microcarrier culture

Summary Three monkey kidney cell lines and primary chicken embryo cells were grown in microcarrier culture. The carrier support was DEAE-Sephadex gel beads at low anion exchange capacity prepared according to a protocol developed at the Massachusetts Institute of Technology. The growth rate of the cells and the final cell density in microcarrier culture was dependent on the concentration of the beads in culture and on the size of the initial cell inoculum. A bead concentration of 1.0 to 2.0 mg of beads/ml of tissue culture medium and a cell inoculum of 20,000 cells/cm² of bead surface appeared to be optimal. The efficiency of the microcarrier culture system was compared to that of stationary and roller bottle cultures. Stationary flasks gave cell densities about twofold higher than maximal densities in roller bottles and about threefold and twofold higher than cell densities in microcarrier culture at a bead concentration of 2.5 and 1.0 mg/ml, respectively. In terms of cell yield per millitier of tissue culture medium, the microcarrier culture was superior to roller bottle and stationary cultures. An advantage of the microcarrier culture system is its suitability for a scale up into large volume production units.     

Evaluation of a microcarrier process for large-scale cultivation of attenuated hepatitis A

Microcarrier culture was investigated for the propagation of attenuated hepatitis A vaccine in the anchorage-dependent human fibroblast cell line, MRC-5. Cells were cultivated at 37°C for one to two weeks, while virus accumulation was performed at 32°C over 21 to 28 days. The major development focus for the microcarrier process was the difference between the cell and virus growth phases. Virus antigen yields, growth kinetics, and cell layer/bead morphology were each examined and compared for both the microcarrier and stationary T-flask cultures. Overall, cell densities of 4–5×10⁶ cells/ml at 5–10 g/l beads were readily attained and could be maintained in the absence of infection at either 37°C or 32°C. Upon virus inoculation, however, substantial cell density decreases were observed as well as 2.5 to 10-fold lower per cell and per unit surface area antigen yields as compared to stationary cultures. The advantages as well as the problems presented by the microcarrier approach will be discussed.     

Giardia lamblia: Evaluation of roller bottle cultivation

A modified “outside-in” roller bottle with a high ratio of surface area to volume was used to cultivate Giardia lamblia. Yields were high, more so when bottles were rotated at 6 rph (9.3 ± 4.0 × 10⁸ trophozoites/bottle) than at 12 rph (4.2 ± 1.9 × 10⁸ trophozoites/bottle). The method was more efficient than stationary tube culture with respect to utilization of culture medium; trophozoite concentration after roller bottle culture (1.7 ± 0.8 × 10⁶ trophozoites/ml) was significantly higher (by a factor of 2.8) than concentrations obtained from stationary tube culture (0.6 ± 0.4 × 10⁶ trophozoites/ml, P < 0.002). Increased yields from roller bottle culture were not accounted for by a reduction in mean trophozoite generation time (roller culture, 10.7 ± 1.2 hr; stationary tube culture, 10.3 ± 0.6 hr) but may be related to prolongation of the period of log phase growth or increased trophozoite survival. Trophozoite yields expressed per unit surface area were significantly higher from roller bottle culture (7.2 ± 3.1 × 10⁵ trophozoites/cm²) than from stationary tubes (1.9 ± 1.0 × 10⁵ trophozoites/cm², P < 0.002). Attempts to cultivate G. lamblia in spin culture using polystyrene beads (Biosilon) as a microcarrier were unsuccessful, trophozoite growth being inhibited rather than promoted. Roller bottle culture of G. lamblia, however, is efficient, economical, and less laborious than stationary tube culture, particularly when more than 10⁸ trophozoites are required.     

Primary suspension culture of calf anterior pituitary cells on a microcarrier surface

In order to achieve a steady-state primary culture system for mammalian cells, with the potential to eventually correlate and control cell function and growth, a serious evaluation of various suspension systems was made. Calf anterior pituitary cells were employed as a differentiated cell type and successfully cultivated in a microcarrier suspension culture system. DEAE-Sephadex was demonstrated to be a satisfactory type of microcarrier. The cells readily attached to the bead and, after a short lag period, they actively proliferated on the bead surface to yield growth of a predominantly epithelial cell type. Under specific conditions the microcarrier supported primary cell growth up to levels of 2 × 10⁶ cells per ml. High bead concentrations inhibited cell growth. The inhibition could be overcome by using proportionately higher cell inoculum so that a concentrated culture with 5 × 10⁶ cells per ml was achieved. The inhibitory effect of high bead concentration was found to be due to the absorption of serum protein and certain growth enhancing factors. The fact that the growth enhancing factors were released from cells during the period of trypsinization and were both thermostable and nondialyzable, seems to suggest one approach to a dialysis culture system. In addition, relatively trauma-free primary cell cultures can be achieved by using explant culture without prior trypsinization. In microcarrier suspensions direct growth of primary rat mammary tumor cells was also demonstrated.     

微载体高密度培养Vero细胞的研究

微载体是动物细胞高密度培养的有效手段。首先在硅化的方瓶中对Cytodex 1、Cy-todex 3、Biosilon、Bellco Glass Microcarrier、CT-1、CT-3、MC-1、CT-28种国产和进口微载体进行了比较和筛选。确定以Biosilon作为Vero细胞高密度培养的首选微载体。用500mlWheaton搅拌瓶探索影响Vero细胞高密度培养的条件,表明50～60mg/ml的微载体浓度、1～2×10⁶/ml的细胞接种密度、适当的通气(95％O_2+5％CO₂)对该细胞的高密度培养具有重要意义。在200ml培养体积的Wheaton搅拌瓶中,微载体浓度为50～60mg/ml,细胞接种密度为9.24×10⁵/ml,搅拌速度为65～85r/min,经25d培养,Vero细胞密度可达2.34×10⁷/ml,表明50～60mg/ml的微载体浓度对培养细胞没有毒性。接着在1.5L CelliGen生物反应器中进行培养,细胞接种密度为4.98×10⁵/ml,培养体积为1.2L,日灌流量从0.20L逐渐加大到3.65L,经22d连接灌流培养,最终细胞密度可达2.05×10⁷/ml。     

Microcarrier culture of vascular endothelial cells on solid plastic beads

The culture of vascular endothelial cells on solid plastic beads is described. A greater than 30-fold increase in cell numbers was achieved in stationary culture medium. The inclusion of fibroblast growth factor slightly improved the rate of growth from low densities. Addition of fresh beads to colonized beads resulted in colonization of the newly introduced microcarrier. In common with the behaviour of endothelium in conventional culture, the cells cultured on beads changed from a fusiform to a polygonal shape after reaching confluence. Cell proliferation was also observed by [³H]thymidine autoradiography of DNA. The fraction of radiolabelled nuclei declined at confluence on each bead, indicating density-inhibition of growth. By electron microscopy, the cells displayed the typical ultrastructural appearance of endothelium. Following transfer of colonized beads to a chromatography column with slow perfusion of the bead bed, cell viability was maintained over a 24 h period and proportional synthesis of prostaglandin I₂ upon stimulation by ionophore A23187 was demonstrated. This simple microcarrier technique allows the generation of large numbers of vascular endothelial cells for subcellular fractionation with economical use of space and medium. When set up as a perfused bead bed, it offers possibilities for the short-term collection of concentrated endothelial metabolites.     

Human interferon production with diploid fibroblast cells grown on microcarriers.

A variety of diploid human fibroblast lines have been successfully grown to high densities (greater than 10(6) cell/ml) on recently developed microcarriers. Interferon induction using poly I.poly C and a superinduction procedure resulted in yields greater than 10,000 units/ml with one cell line. A direct comparison of microcarrier cultures to roller bottle cultures showed equivalent interferon yields on a per cell basis and some apparent differences relating to optimum inducer concentrations and kinetics of interferon accumulation.     

转瓶培养与生物反应器微载体培养乙脑病毒的比较

分别用15L转瓶与15L生物反应器微载体(2.5g/L CytodexⅢ)系统培养Vero细胞并接种乙型脑炎病毒(简称乙脑病毒)。转瓶培养Vero细胞7~8d,细胞数最高能达到8×108;当单层细胞长至3.0~4.5×108时接种乙脑病毒,病毒滴度能达到6.5~6.98 lg PFU/ml,并能够连续收获4~5次;采用微载体系统培养Vero细胞,细胞密度最高能达到170×108;当单层细胞长至60~70×108时接种乙脑病毒,病毒滴度能达到7~7.5 lg PFU/ml,并能够连续收获13~15次。两种方式培养的乙脑病毒收获液分别经灭活、浓缩、柱层析纯化后制备Vero细胞乙脑纯化疫苗,各项检定指标均符合《中国药典》的相关要求。     

Expansion of mouse sertoli cells on microcarriers

Background: Sertoli cells (SCs) have been described as the ‘nurse cells’ of the testis whose primary function is to provide essential growth factors and create an appropriate environment for development of other cells [for example, germinal and nerve stem cells (NSCs), used here]. However, the greatest challenge at present is that it is difficult to obtain sufficient SCs of normal physiological function for cell transplantation and biological medicine, largely due to traditional static culture parameter difficult to be monitored and scaled up. Objective: Operational stirred culture conditions for in vitro expansion and differentiation of SCs need to be optimized for large‐scale culture. Materials and methods: In this study, the culturing process for primary SC expansion and maintaining lack of differentiation was optimized for the first time, by using microcarrier bead technology in spinner flask culture. Effects of various feeding/refreshing regimes, stirring speeds, seed inoculum levels of SCs, and concentrations of microcarrier used for expansion of mouse SCs were also explored. In addition, pH, osmotic pressure and metabolic variables including consumption rates of glucose, glutamine, amino acids, and formation rates of lactic acid and ammonia, were investigated in culture. Results: After 6 days, maximal cell densities achieved were 4.6 × 10⁶ cells/ml for Cytodex‐1 in DMEM/FBS compared to 4.8 × 10⁵ cells/ml in static culture. Improved expansion was achieved using an inoculum of 1 × 10⁵ cells/ml and microcarrier concentration of 3 mg/ml at stirring speed of 30 rpm. Results indicated that medium replacement (50% changed everyday) resulted in supply of nutrients and removal of waste products inhibiting cell growth, that lead to maintenance of cultures in steady state for several days. These conditions favoured preservation of SCs in the undifferentiated state and significantly increased their physiological activity and trophic function, which were assessed by co‐culturing with NSCs and immunostaining. Conclusion: Data obtained in this study demonstrate the vast potential of this stirred culture system for efficient, reproducible and cost‐effective expansion of SCs in vitro. The system has advantages over static culture, which has major obstacles such as lower cell density, is time‐consuming and susceptible to contamination.     

Production of reovirus type-1 and type-3 from Vero cells grown on solid and macroporous microcarriers

Two strains of reovirus were propagated in Vero cells grown in stationary or microcarriers cultures. Vero cells grown as monolayers on T-flasks or in spinner cultures of Cytodex-1 or Cultispher-G microcarriers could be infected with reovirus serotype 1, strain Lang (T1L), and serotype 3, strain Dearing (T3D). A regime of intermittent low speed stirring at reduced culture volume was critical to ensure viral infection of cells in microcarrier cultures. The virus titre increased by 3 to 4 orders of magnitude over a culture period of 150 h. Titres of the T3D reovirus strain were higher (43%) compared to those of the T1L strain in all cultures. Titres were significantly higher in T-flask and Cytodex-1 microcarrier cultures compared to Cultispher-G cultures with respect to either reovirus type. The viral productivity in the microcarrier cultures was dependent upon the multiplicity of infection (MOI) and the cell/bead ratio at the point of infection. A combination of high MOI (5 pfu/cell) and high cell/bead loading (>400 for Cytodex-1 and >1,000 for Cultispher-G) resulted in a low virus productivity per cell. However, at low MOI (0.5 pfu/cell) the virus productivity per cell was significantly higher at high cell/bead loading in cultures of either microcarrier type. The maximum virus titre (8.5 x 10(9) pfu/mL) was obtained in Cytodex-1 cultures with a low MOI (0.5 pfu/cell) and a cell/bead loading of 1,000. The virus productivity per cell in these cultures was 4,000 pfu/cell. The lower viral yield in the Cultispher-G microcarrier cultures is attributed to a decreased accessibility of the entrapped cells to viral infection. The high viral productivity from the Vero cells in Cytodex-1 cultures suggests that this is a suitable system for the development of a vaccine production system for the Reoviridae viruses.     

原代地鼠肾细胞及狂犬病毒不同培养方式的研究

目的通过比较原代地鼠肾细胞在转瓶、微载体、细胞工厂的3种培养方式的培养效果,为原代地鼠肾细胞选择一种易扩大规模、培养高质量细胞的培养方式,进而提高狂犬病毒的产量。方法消化取得的细胞悬液分别在转瓶、微载体、细胞工厂中培养,通过显微镜观察细胞形态、计数等结果比对培养的差别。结果细胞工厂可以很好地培养原代地鼠肾细胞和狂犬病毒;而细胞在微载体上贴附性差,生长不好。结论实验结果表明细胞工厂可以取代转瓶,用于大规模培养原代地鼠肾细胞扩大狂犬病毒的产量。     

Scale-up of suspension and anchorage-dependent animal cells

Alternative culture processes for laboratory scale-up (to 20 L) are described for both suspension and anchorage-dependent cells. Systems range from simple multiple culture units such as the roller bottle, through stirred suspension and microcarrier unit bioreactors, to highly sophisticated perfusion culture capable of maintaining cells at densities of about 10⁸/mL. Critical parameters in scale-up are discussed, and the advantages and disadvantages of each culture system are critically evaluated.     

Production and glycosylation of recombinant beta-interferon in suspension and cytopore microcarrier cultures of CHO cells

Microcarriers are suitable for high-density cultures of cells requiring surface attachment and also offer the advantage of easy media removal for product recovery. We have used the macroporous microcarriers Cytopore 1 and 2 for the growth of CHO cells producing recombinant human beta-interferon (beta-IFN) in stirred batch cultures. Although these cells may grow in suspension, in the presence of Cytopore microcarriers they become entrapped in the inner bead matrix where they can be maintained at high densities. Cell growth rates were reduced in microcarrier cultures compared to suspension cultures. However, the beta-IFN yield was up to 3-fold greater as a result of an almost 5-fold higher specific productivity. Maximum productivity was found in cultures containing 1.0 mg/mL of Cytopore 1 or 0.5 mg/mL of Cytopore 2 with a cell/bead ratio of 1029 and 822, respectively. Beta-IFN molecules aggregated in the later stages of all cultures, causing a decrease in response by ELISA. However, the degree of aggregation was significantly less in the microcarrier cultures. The N-linked glycans from beta-IFN were isolated and analyzed by normal phase HPLC. There was no apparent difference in the profile of glycans obtained from each of the suspension and Cytopore culture systems. This suggests that Cytopore microcarriers may be useful in bioprocess development for enhanced recombinant glycoprotein production without affecting the glycosylation profile of the protein.     

Application of a serum-free medium for the growth of Vero cells and the production of reovirus

Two strains of reovirus (serotype 1 Lang/TIL and serotype 3 Dearing/T3D) were propagated in Vero cells grown in stationary or agitated cultures in a serum-free medium, M-VSFM. Solid microcarriers (Cytodex-1) were used to support cell growth in agitated cultures with a normal doubling time of 25 h. Cell yields of 1 x 10(6) cells/mL were obtained from an inoculum of 2 x 10(5) cells/mL in 4 days in microcarrier cultures. The growth profile and cell yield was not significantly different from serum-supplemented cultures. The virus titer increased by 3-4 orders of magnitude over a culture period of 150 h. The maximum virus titer in stationary cultures reached >1 x 10(9) pfu/mL for both strains of reovirus in M-VSFM. M-VSFM also supported high viral yields in microcarrier cultures. Both the specific productivity and final viral yield was higher in M-VSFM than serum-supplemented cultures. The high viral productivity suggests that this is a suitable system for the production of reovirus as an oncolytic agent for human therapeutic use.     

Attachment characteristics of normal human cells and virus-infected cells on microcarriers

The attachment kinetics of normal and virus-infected LuMA cells were studied to improve the production of live attenuated varicella viruses in human embryonic lung (LuMA) cells. Normal LuMA cells and LuMA cells infected by varicella virus at various cytopathic effects (CPE) were grown on microcarriers. Ninety-three percent of suspended LuMA cells attached to the solid surface microcarriers within fifteen minutes and cell viability was greater than 95% when the cell suspension was stirred. Low serum levels did not affect the attachment rate of virus-infected cells in the microcarrier culture system. Kinetic studies showed that varicella infected cells had a lower attachment rate than normal LuMA cells. Virus inoculum (= infected cells) at low CPE showed a relatively better attachment rate on cell-laden microcarriers than virus inoculum at a higher CPE. Maximum titers were obtained at 2 days post-infection. Based on cell densities, the use of viral inoculum showing a 40% CPE led to an approximately 2- and 1.2-fold increase in the cell associated and in cell free viruses, respectively, than a virus inoculum with a CPE of 10%.However, the ratio of cell-free to cell-associated virus in a microcarrier culture was very low, approximately0.04–0.06. These studies demonstrate that the virus inoculum resulting in a high CPE yielded a high production of cell-associated and cell-free virus in microcarrier cultures because of the high cellular affinity of the varicella virus. This revised version was published online in August 2006 with corrections to the Cover Date.     

Stationary and microcarrier cell culture processes for propagating Japanese encephalitis virus

Inactivated mouse-brain-derived vaccines for Japanese encephalitis virus (JEV) have been used for many years. Recently, attempts have been made to employ cultured Vero cells to replace mouse brain tissues for developing cell-culture-derived vaccines that will be more suitable for worldwide usage. In this study, JEV replication processes in Vero and BHK cells and between stationary and microcarrier culture systems were investigated. Our results demonstrated that a stationary Vero cell culture system produced higher viral titers of JEV, including the Beijin-1 vaccine strain and the attenuated strain CH2195LA, than microcarrier culture did. BHK cells showed less significant differences in their replication kinetics between stationary and microcarrier cultures. Reducing serum concentration during infection led to an overall decrease of JEV production in Vero cells but an increase in BHK cells. By establishing a complete serum-free Vero cell culture, the microcarrier system resulted in a more than 4-log lowered yield compared to that of the stationary culture for JEV production. Thus, the stationary culture is the most efficient system for JEV production from cultured Vero cells.     

Growth of Fish Cell Lines on Microcarriers

Microcarrier beads were evaluated as substrates for the propagation of five anchorage-dependent fish cell lines. Growth of rainbow trout gonad (RTG-2) and Atlantic salmon cells was limited on microcarriers maintained in suspension. However, stationary microcarriers were suitable substrates for the growth of RTG-2, AS, Chinook salmon embryo (CHSE-214), and fathead minnow cells. Cell yields ranged from 2 × 10⁶ to 2.9 × 10⁶ cells per ml, representing 7- to 10-fold increases over the initial cell concentrations. The yield of new RTG-2 cells per unit volume of growth medium was 2.8 times greater in microcarrier cultures than in standard monolayer cultures. Northern pike cells failed to grow on microcarriers. Yields of infectious pancreatic necrosis virus propagated in microcarrier cultures of RTG-2 cells were more than twice the yields in standard monolayer cultures. The greater economy of microcarrier cultures in terms of growth vessel and medium requirements holds great promise for the large-scale production of anchorage-dependent fish cell cultures and fish viruses.     

Establishment of Orthosiphon stamineus Cell Suspension Culture for Cell Growth

Callus of Orthosiphon stamineus could be induced successfully from petiole, leaf and stem tissues but not roots when cultured on MS medium containing different concentration of NAA (0–4.0 mg l^–1) and 2,4-D (0–2.0 mg l^–1). Highest fresh weight callus production was obtained from leaf explants and those with best friability were obtained on MS medium plus 1.0 mg l^–1 2,4-D plus 1.0 mg l^–1 NAA. Cell suspension cultures were established from these cultures. The appropriate cell inoculum size for the best cell growth was 0.75 g of cells in 20 ml culture medium. Cell suspension culture using MS medium supplemented with 1.0 mg l^–1 2,4-D promoted the best cell growth with maximum biomass of 8.609 g fresh weight and 0.309 g dry weight 24 days after inoculation. Cells that grew in MS medium supplemented with 1.0 mg l^–1 2,4-D reached the stationary growth phase in 15 days as compared to the cells that grew in MS medium supplemented with 1.0 mg l^–1 2,4-D + 1.0 mg l^–1 NAA reached the stationary phase in 24 days. MS medium supplemented with 1.0 mg l^–1 2,4-D was considered as the maintenance medium for maintaining the optimum cell growth of O. stamineus in the cell suspension cultures with 2-week interval subculture.     

Comparisons of microcarrier cell culture processes in one hundred mini-liter spinner flask and fifteen-liter bioreactor cultures

Microcarrier cell culture process can be used to culture anchorange-dependent cells in large bioreactor vessels. The process performance in large bioreactors is usually less prominent than that in spinner flask vessels and bench scale reactors. In this study we investigated the microcarrier cell culture processes in 100?ml spinner flask and 15-liter bioreactor cultures, including the kinetics for cell attachment, cell growth and the production of Japanese encephaltilis vaccine strain (Beijing-1) virus. Under a fixed concentration of microcarrier and cell density used in inoculations, the attachment kinetics of Vero cells on Cytodex 1 microcarrier in a 15-liter bioreactor vessel was 2 folds slower than with 100?ml spinner flask culture. Virus replication in 15-liter bioreactor culture also revealed an approximately one day lag-time compared to 100?ml spinner flask culture. Findings presented herein provide valuable information for designing and operating microcarrier cell culture processes in large bioreactor vessels.     

Expansion of mouse embryonic stem cells on microcarriers

Embryonic stem (ES) cells have been shown to differentiate in vitro into a wide variety of cell types having significant potential for tissue regeneration. Therefore, the operational conditions for the ex vivo expansion and differentiation should be optimized for large-scale cultures. The expansion of mouse ES cells has been evaluated in static culture. However, in this system, culture parameters are difficult to monitor and scaling-up becomes time consuming. The use of stirred bioreactors facilitates the expansion of cells under controlled conditions but, for anchorage-dependent cells, a proper support is necessary. Cytodex-3, a microporous microcarrier made up of a dextran matrix with a collagen layer at the surface, was tested for its ability to support the expansion of the mouse S25 ES cell line in spinner flasks. The effect of inocula and microcarrier concentration on cell growth and metabolism were analyzed. Typically, after seeding, the cells exhibited a growth curve consisting of a short death or lag phase followed by an exponential phase leading to the maximum cell density of 2.5-3.9 x 10(6) cells/mL. Improved expansion was achieved using an inoculum of 5 x 10(4) cells/mL and a microcarrier concentration of 0.5 mg/mL. Medium replacement allowed the supply of the nutrients and the removal of waste products inhibiting cell growth, leading to the maintenance of the cultures in steady state for several days. These conditions favored the preservation of the S25 cells pluripotent state, as assessed by quantitative real-time PCR and immunostaining analysis.