Analysis of cell-to-bubble attachment in sparged bioreactors in the presence of cell-protecting additives

To investigate the mechanisms of cell protection provided by medium additives against animal cell injury in sparged bioreactors, we have analyzed the effect of various additives on the cell-to-bubble attachment process using CHO cells in suspension. Cell-to-bubble attachment was examined using three experimental techniques: (1) cell-bubble induction time analysis (cell-to-bubble attachment times); (2) forming thin liquid films and observing the movement and location of cells in the thin films; and (3) foam flotation experiments. The induction times we measured for the various additives are as follows: no additive (50 to 500 ms), polyvinyl pyrrolidone (PVP: 20 to 500 ms), polyethylene glycol (PEG: 200 to 1000 ms), 3% serum (500 to 1000 ms), polyvinyl alcohol (PVA: 2 to 10 s), Pluronic F68 (5 to 20 s), and Methocel (20 to 60 s). In the thin film formation experiments, cells in medium with either F68, PVA, or Methocel quickly flowed out of draining thin liquid films and entered the plateau border. When using media with no additive or with serum, the flow of cells out of the thin liquid film and film drainage were slower than for media containing Pluronic F68. PVA, or Methocel. With PVP and PEG, the thin film drainage was much slower and cells remained trapped in the film. For the foam flotation experiments, a separation factor (ratio of cell concentration in the foam catch to that in the bubble column) was determined for the various additives. In the order of increasing separation factors (i.e., increasing cell attachment to bubbles), the additives are as follows: Methocel, PVA, Pluronic F68, 3% serum, serum-free medium with no additives, PEG, and PVP. Based on the results of these three different cell-to-bubble attachment experiments, we have classified the cell-protecting additives into three groups: (1) Pluronic F68, PVA, and Methocel (reduced cell-to-bubble attachment); (2) PEG and PVP (high or increased cell-to-bubble attachment); and (3) FBS (reduced cell attachment butslower drainage films compared with F68, PVA, and Methocel with some cell entrapment in those films). These phenomena are discussed in relation to the interfacial properties of the media reported in a companion Study (this issue). (c) 1995 John Wiley & Sons Inc.     

Polyvinyl alcohol and polyethylene glycol as protectants against fluid-mechanical injury of freely-suspended animal cells (CRL 8018).

Two identical bioreactors run in parallel were used to examine the phenomenological characteristics of two additives, polyethylene glycol (PEG) and polyvinyl alcohol (PVA), used as protectants against fluid-mechanical cell damage. Cell-protecting ability was evaluated by comparing apparent cell growth rates of freely suspended CRL-8018 hybridoma cells cultured in serum-free medium under surface aerated conditions whereby cell damage is due to bubble entrainment and breakup. PEG of various molecular weights was used to determine whether the size of the polymer has significant effects on PEG's cell-protecting capabilities. All the PEG's with molecular weights larger than 1400 showed similar protective effects. The effect of PEG concentration was then evaluated and results showed that concentrations greater than 0.05% w/v did not significantly improve the cell-protecting properties. Direct comparisons made between the PVA, PEG, and pluronic F68 as cell protectants showed that PEG protected cells better than F68 and that PVA provided even better protection than PEG. The mechanism of protection, fluid-mechanical or biological in nature, was examined by growing the cells in additive from the beginning of the experiment (long-term exposure), or adding the additive after the cells had been agitated at rates detrimental to the cells (short-term exposure). In agreement with results reported previously on PEG and F68, fast-acting protection was seen. This implies a fluid-mechanical rather than a biological protection mechanism. In an attempt to correlate interfacial properties of the resulting media with shear protection, interfacial tension and viscosity measurements of all the media were made. On the basis of these measurements, we find no definitive correlations for evaluating these additives' cell-protecting capabilities.     

Effects of methocel A15LV, polyethylene glycol, and polyvinyl alcohol on CD13 and CD33 receptor surface content and metabolism of HL60 cells cultured in stirred tank bioreactors

Flow cytometry was used to examine the effect of hydrodynamic forces in a stirred tank bioreactor on the CD13 and CD33 receptor surface content of HL60 (human promyelocytic leukemia) cells. A step increase in agitation rate from 80 to 400 rpm reduced the HL60 cell apparent growth rate and increased the CD13 receptor surface content per cell, on average, by 95%. In contrast, this step increase in agitation rate to 400 rpm decreased the CD33 receptor surface content per cell, on average, by 10%. The protective effects of 0.1% Methocel A15LV, polyethylene glycol (PEG), and polyvinyl alcohol (PVA) on CD13 and CD33 receptor surface content were examined under agitation at 300 rpm in parallel 2 L bioreactor runs. The average CD33 receptor surface content was unaffected by the presence of Methocel A15LV or PEG, while PVA had a slight protective effect. In contrast, in terms of CD13 receptor content, HL60 cells agitated at 300 rpm with Methocel A15LV, PEG, or PVA behaved like cells agitated at 80 rpm with no media additives (McDowell and Papoutsakis, 1998). That is, Methocel A15LV, PEG, and PVA prevented the transduction of mechanical forces which affect CD13 cell content. HL60 cells cultured with 0.1% A15LV, PEG or PVA under conditions of mild agitation (60 rpm) in spinner flasks exhibited glucose consumption and lactate production rates that were approximately 20% lower than values of cultures containing no additive. Under conditions of agitation at 300 rpm in the 2 L bioreactor, the presence of A15LV, PEG, and PVA reduced the HL60 glucose consumption and lactate production rates by approximately 50%. Thus, media additives can dramatically reduce lactate accumulation in agitated bioreactors due to cell growth, in addition to providing protection from cellular injury.     

The meiotic response of cumulus cell-enclosed mouse oocytes to follicle-stimulating hormone in the presence of different macromolecules.

Experiments were carried out to determine the effect of different macromolecules on the follicle-stimulating hormone (FSH)-induced maturation of mouse oocytes in culture. Cumulus cell-enclosed oocytes (CEO) were isolated from gonadotropin-primed mice and maintained in meiotic arrest for 17-18 h with the cAMP analogue, dibutyryl cAMP (dbcAMP). Germinal vesicle breakdown (GVB) was stimulated by the addition of FSH. Medium was supplemented with either no macromolecule or with varying concentrations of polyvinylpyrrolidone (PVP), polyvinylalcohol (PVA), crystallized bovine serum albumin (BSA), or fetal bovine serum (FBS). Oocyte maturation in all FSH-free cultures occurred at a frequency of about 30% or below. High frequencies of maturation were achieved when FSH was added to macromolecule-free medium or to cultures containing PVP, PVA, or BSA. Crystallized BSA was the most effective of these in supporting stimulation of maturation (94% GVB at 3 mg/ml, compared with 72-74% with synthetic polymer-supplemented or macromolecule-free media). The BSA effect was not due to contaminating fatty acids, and a less pure fraction V BSA was not as effective in supporting FSH-induced maturation. FBS suppressed FSH stimulation of maturation in a dose-dependent fashion. Sera from pigs, goats, horses, and rats were also inhibitory, but bovine calf serum (BCS) permitted a high maturation frequency (80% GVB). When added to medium containing either FBS or BCS, crystallized BSA had no effect on FSH-stimulated maturation, but fraction V BSA suppressed maturation in both serum-supplemented media. Under no conditions did FSH stimulate maturation in cumulus cell-free oocytes. These results demonstrate that hormone-induced oocyte maturation is supported in vitro by nonprotein polymers as well as BSA and that the behavior of the oocyte-cumulus cell complex depends on the purity of the BSA sample. In addition, serum contains inhibitory factors that suppress the positive response to FSH. Thus, the choice of macromolecular supplement is of critical importance when testing the hormone responsiveness of isolated cumulus cell-enclosed oocytes in culture.     

Protection mechanisms of freely suspended animal cells (CRL 8018) from fluid-mechanical injury. Viscometric and bioreactor studies using serum, pluronic F68 and polyethylene glycol

We use bioreactor and viscometric studies to examine the mechanism by which three additives, fetal bovine serum (FBS), pluronic F68, and polyethylene glycol (PEG), protect the freely suspend CRL-8018 cells from damage due to interactions with bubbles in agitated bioreactors. In bioreactor studies, the protective effect of an addictive could be due to either changes in the ability of the cell resist shear (biological mechanism) or to changes in the medium properties that effect the level or frequency of forces experienced by the cells (physical mechanism). Bioreactor studies show that protection by all three addictives occurs whether the cells are grown in the presence of the addictives (long exposure) or the addictives are added to medium after the cells were exposed to detrimental agitation intensity (short exposure). In the viscometric studies, exposure of cells to laminar shear in the absence of gas-liquid interfaces assesses only the ability of the cells to resist a constant level of shear in a medium with or without an additive. Viscometric studies show that prolonged exposure to FBS makes the cells more shera tolerant, but that short (30-120 min) exposure to FBS does not affect their shear tolerance. We thus conclude that the protective effect of FBS in bioreactors id of both physical and biological nature. The biological contribution is metabolic in nature rather than fast acting. Viscometric studies show that either long or short exposure of the cells to either F68 or PEG does not make the cells more shear tolerant. WE therefore conclude that the protective effect of F68 and PEG does not make the cells more shear tolerant. We therefore conclude that the protective effect of F68 and PEG in bioreactors is physical in nature.     

Chinese hamster ovary cells cultured in low concentrations of fetal bovine serum: cloning efficiency, growth in suspension, and selection of drug-resistant mutant phenotypes

Reducing serum concentrations in media provides a potential cost advantage. To determine whether such media could be used for applied mutagenesis assays, we measured cloning efficiency and growth parameters in suspension of Chinese hamster ovary cells cultured in reduced serum with or without additives (1 microgram/ml insulin, 3 X 10(-7) M linoleic acid, 1 X 10(-8) M H2SeO3) or bovine serum albumin (BSA, 1% wt/vol). With the additives and less than or equal to 0.5% fetal bovine serum (FBS), Ham's F12 medium (without hypoxanthine and thymidine) was more optimal than alpha Eagle's minimum essential medium (MEM) (without ribosides and deoxyribosides) for low density cloning and high density suspension growth. Acceptable cloning efficiencies were obtained with 2% FBS plus BSA without additives in either medium; the addition of BSA resulted in improved colony size and more compact colony morphology. In alpha MEM, satisfactory growth rates and maximum saturation densities in suspension culture were obtained only with 5% FBS; in Ham's F12, 1% FBS + deoxycytidine + BSA yielded satisfactory suspension growth. Spontaneous mutant frequencies were compared for each medium containing 10% dialyzed FBS (DFBS), 1% FBS plus BSA, or 2% FBS plus BSA. The spontaneous frequency of azaadenine-resistant phenotypes (mutant at the aprt locus) in 1% FBS plus BSA was significantly lower than the frequency observed in 2% FBS plus BSA or 10% DFBS. Frequencies of spontaneous mutants resistant to thioguanine (hgprt locus) or fluorodeoxyuridine (tk locus) were similar with 10% DFBS, 1% FBS plus BSA, or 2% FBS plus BSA. Compared to alpha MEM with 10% DFBS, frequencies of drug-resistant mutants induced by ethyl methanesulfonate or mitomycin C (MMC) were not significantly lower in alpha MEM with 2% FBS plus BSA; observed mutant frequencies induced by dimethylnitrosamine or benzo(a)pyrene seemed to be decreased at lower survival levels.     

Mechanical agitation of hybridoma suspension cultures: Metabolic effects of serum, pluronic F68, and albumin supplements

Metabolic effects of the medium supplements, fetal bovine serum (FBS), Pluronic F68, and bovine serum albumin (BSA) were compared for agitated bioreactor cultures of hybridoma cells. Agitation speeds up to 600 rpm, without entrainment of gas bubbles by sparging or vortex formation, allowed examination of cell interactions with turbulent fluid forces. For cultures in FBS-supplemented RPMI media, there was no significant effect of intense turbulent fluid shear on cell growth, metabolism, or antibody, production. Serum-free cultures (Pluronic F68 or BSA supplements) at 600 rpm demonstrated greatly increased glycolysis rates during exponential growth relative to controls. Nutrient limitations caused increased rates of decline of the viable cell concentrations and a reduction in final antibody titers by around 70%. The Pluronic F68 and BSA supplements did not lead to cell protection by modifying metabolism under conditions of intense turbulent fluid shear. Supplementing the protein-free medium with FBS reduced glycolysis rates in exponential growth phase, but this did not prevent a high rate of viable cell decline and low antibody titers. We concluded that FBS does not have a metabolic effect on cells subjected to intense turbulent fluid shear. Although the agitation conditions employed in this study were more intense than generally required for agitated bioreactor culture of hybridomas, we have demonstrated the importance of considering metabolic effects of turbulent fluid forces on cultures using nutrient-rich basal media, in addition to the considerations of gas bubble effects described by other workers. (c) 1992 John Wiley & Sons, Inc.     

Chinese hamster ovary cells cultured in low concentrations of fetal bovine serum: Cloning efficiency,growth in suspension,and selection of drug-resistant mutant phenotypes

Summary Reducing serum concentrations in media provides a potential cost advantage. To determine whether such media could be used for applied mutagenesis assays, we measured cloning efficiency and growth parameters in suspension of Chinese hamster ovary cells cultured in reduced serum with or without additives (1 μg/ml insulin, 3×10⁻⁷ M linoleic acid, 1×10⁻⁸ M H₂SeO₃) or bovine serum albumin (BSA, 1% wt/vol). With the additives and ≤0.5% fetal bovine serum (FBS), Ham’s F12 medium (without hypoxanthine and thymidine) was more optimal than alpha Eagle’s minimum essential medium (MEM) (without ribosides and deoxyribosides) for low density cloning and high density suspension growth. Acceptable cloning efficiencies were obtained with 2% FBS plus BSA without additives in either medium; the addition of BSA resulted in improved colony size and more compact colony morphology. In alpha MEM, satisfactory growth rates and maximum saturation densities in suspension culture were obtained only with 5% FBS; in Ham’s F12, 1% FBS+deoxycytidine+BSA yielded satisfactory suspension growth. Spontaneous mutant frequencies were compared for each medium containing 10% dialyzed FBS (DFBS), 1% FBS plus BSA, or 2% FBS plus BSA. The spontaneous frequency of azaadenine-resistant phenotypes (mutant at theaprt locus) in 1% FBS plus BSA was significantly lower than the frequency observed in 2% FBS plus BSA or 10% DFBS. Frequencies of spontaneous mutants resistant to thioguanine (hgprt locus) or fluorodeoxyuridine (tk locus) were similar with 10% DFBS, 1% FBS plus BSA, or 2% FBS plus BSA. Compared to alpha MEM with 10% DFBS, frequencies of drug-resistant mutants induced by ethyl methanesulfonate or mitomycin C (MMC) were not significantly lower in alpha MEM with 2% FBS plus BSA; observed mutant frequencies induced by dimethyl-nitrosamine or benzo(a)pyrene seemed to be decreased at lower survival levels. This work was performed under the auspices of the U.S. Department of Energy by the Lawrence Livermore National Laboratory under Contract W-7405-ENG-48 and supported by the Environmental Protection Agency under Interagency Agreements IAG-D5-E681-AN and AO.     

Improved in vitro development of porcine embryos with different energy substrates and serum

The effect of replacing 5.5 mM glucose in North Carolina State University (NCSU)-23 medium with 0.5 mM pyruvate/5.0 mM lactate on porcine IVF embryo development was investigated in Experiment 1. Culturing embryos with pyruvate/lactate for 7 days or with pyruvate/lactate from Days 0 to 2, and then glucose from Days 2 to 7 improved cleavage rates. In Experiment 2, embryos were cultured for 7 days in pyruvate/lactate containing NCSU-23 medium supplemented with 0.05% PVA, 0.4% BSA or 10% fetal bovine serum (FBS). The BSA supplement increased the rates of cleavage, blastocyst formation, and the number of total cells in blastocysts. In Experiment 3, embryos were cultured in pyruvate/lactate containing NCSU-23 medium supplemented with 0.4% BSA for 7 days (BSA-PL), 0.4% BSA from Days 0 to 4 and then 10% FBS from Days 4 to 7 (BSA-PL-->F ) or 0.4% BSA from Days 0 to 7 with addition of 10% FBS (BSA-PL + F ) at Day 4. More blastocysts in BSA-PL--> F and hatching or hatched blastocysts in BSA-PL-->F and BSA-PL+F were obtained. Total cell number in blastocysts derived from BSA-PL-->F and BSA-PL+F were increased. Our results demonstrated that supplementing pyruvate/lactate containing NCSU-23 medium with 0.4% BSA for 4 days and replacing it with 10% FBS for another 3 days improved porcine IVF embryo development.     

Optimization of conditions for production of sago starch-based foam

Production of sago starch-based foam involved mixing of sago starch with polyvinyl alcohol (PVA) or polyvinyl pyrrolidone (PVP) followed by preparation of electron beam irradiated sago starch/PVA and sago starch/PVP sheets and expanding them in a microwave. The results revealed that good foams with high linear expansion and closed cell structure can be produced from 25:15 of sago starch:PVA and 30:10 of sago starch:PVA blends prepared at 80 °C and electron beam irradiated at 15 kGy or 10 kGy for the cross-linking process. An increment of sago starch in the blends enhanced the linear expansion of the foams produced. Change in the blend morphology was observed when it was exposed to higher irradiation doses as electron beam irradiation induced the cross-linking in PVA and PVP, and leaching of amylose and amylopectin from the starch granules. Sago starch/PVA blend is more suitable for foam production because it produced flexible and glossy foam as compared to sago starch/PVP blend which produced very rigid foam.     

Measurement of hydrophobic interactions of mammalian cells grown in culture

An assay was developed to measure the hydrophobic interactions of commonly used mammalian cell lines grown in culture. The assay depends on the loss of cells from an aqueous suspension following vortexing with a hydrophobic oil phase. This allowed the determination of a hydrophobicity index, which was significantly higher for Chinese Hamster Ovary (CHO) cells than either a murine hybridoma (CC9C10) or a myeloma (SP2/0). This suggests that CHO cells may have a higher intrinsic cell surface hydrophobicity. The assay was also used to study the effect of different additives on the hydrophobic interactions of the cells. A dose-dependent effect was shown for the non-ionic surfactant, Pluronic F68, in reducing the hydrophobic interaction of the CHO cells. However, the pattern of the decrease due to Pluronic F68 was different for each cell line. A higher concentration of Pluronic F68 (0.2%) was required to eliminate the hydrophobic interactions of CHO cells compared to either myelomas or hybridomas, where only 0.05% was required to reduce these interactions to a similar level. Several oils were found suitable for this assay although canola oil maximized the sensitivity of the measured changes. The assay may be useful in monitoring changes in the hydrophobic interactions of mammalian cells during growth in bioreactors. This may be important in optimizing the concentration of cell protectants such as Pluronic F68 in agitated cultures.     

The presence of synthetic polymers in the maturation medium affects the cryotolerance and developmental capacity after parthenogenic activation of vitrified goat oocytes

The purpose of this present study is to assess if addition of the synthetic polymers in maturation medium can influence cryotolerance and subsequently embryonic development of mammalian oocytes. We examined the roles of two polymers, including polyvinyl alcohol (PVA) and polyvinylpyrrolidone (PVP), on in vitro maturation (IVM), embryonic developmental capacity, and cryotolerance of goat oocytes. The present study includes two parts. At first, goat cumulus−oocyte complexes (COCs) were matured in a medium supplemented with 10% fetal bovine serum (FBS), 3 mg/ml PVP, or 1 mg/ml PVA, respectively. Data of oocyte with first polar body, cleavage, and blastocyst following parthenogenetic activation (PA) were recorded. Secondly, after maturation in the above medium, oocytes were vitrified using the Cryotop technique and then the morphology, cleavage and blastocyst formation of vitrified oocytes have been checked. The results demonstrated that the adding of PVP or PVA in maturation medium can't affect IVM of goat oocytes in comparison with FBS, as concern cumulus cell expansion, first polar body formation, and embryonic development. Additionally, without plunging into liquid nitrogen, only exposure to the vitrification and warming solutions cannot also influence the quality of oocytes, in terms of morphology, cleavage, and blastocyst formation. However, after IVM with synthetic polymers and vitrification, the ratio of oocytes with standard morphology in PVP or PVA group was only 59.47% ± 3.56% or 54.86% ± 5.19%, respectively, and was significantly less than that in the FBS group (89.37% ± 4.52%, P < 0.05). Furthermore, the cleavage ratio of oocytes in PVP or PVA group was 37.41% ± 4.17% or 27.71% ± 3.91% and was considerably less than that in the FBS group (64.97% ± 4.69%, P < 0.05). In addition, the cleavage ratio in PVP group was statistically higher than that in PVA group (P < 0.05). In terms of blastocyst development, a significant difference was observed between the synthetic polymer group and the FBS group (24.96% ± 3.62%, P < 0.05). However, the blastocyst ratio in the PVA group (7.51% ± 1.68%) was statistically less than the PVP groups (13.20% ± 4.59%, P < 0.05) and the FBS group (P < 0.05). In conclusion, two potential serum replacements, either PVP or PVA, can support IVM and embryonic development of goat oocytes at the concentration used in this study. But IVM with synthetic polymers supplemented to maturation medium may reduce the cryotolerance of oocytes. Additionally, the supportive function of PVP on embryonic development of vitrified oocytes might be better than that of PVA.     

Effects of different cryoprotectants on the viability and biological characteristics of porcine preadipocyte

Effective techniques for the cryopreservation of porcine preadipocytes could increase the usefulness of these cells as a model in obesity studies. The objective of this study was to test the effects of the following cryoprotective agents (CPAs) on the cytotoxicity, post-thaw survival, proliferation and differentiation capacity of porcine preadipocytes: ethylene glycol (EG), dimethyl sulphoxide (Me2SO), polyvinylpyrrolidone (PVP), Me2SO+PVP, and no-CPA. In addition to the CPAs, the CPA medium contained 80% DMEM/F12 plus 10% FBS. Trypan blue exclusion tests showed that among the CPA treatments in this study, only EG was toxic to porcine preadipocytes. The highest survival rate (94.96%) and cell viability were obtained when preadipocytes were cryopreserved with 10% PVP. Morphologically, PVP cryopreserved preadipocytes resembled fibroblasts and most underwent attachment, proliferation, and growth arrest with subsequent accumulation of intracellular lipid droplets before becoming mature adipocytes. There were no significant differences in the GPDH activity between adipocytes in the PVP treatment and primary cells from days 3 to 10 of the culture. Analysis of RT-PCR confirmed that there was no significant difference of PPARgamma2 mRNA levels between the cells in the 10% PVP treatment and primary cells. In summary, porcine preadipocytes cryopreserved with DMEM/F12 medium containing 10% PVP and 10% FBS have high survival rate and proliferation potential. Furthermore, the cryopreserved cells synthesize a range of markers that are consistent with this cell type. We conclude that 10% PVP is a suitable CPA for porcine preadipocytes.     

Foaming and media surfactant effects on the cultivation of animal cells in stirred and sparged bioreactors.

Foam formation and the subsequent cell damage/losses in the foam layer were found to be the major problems affecting cell growth and monoclonal antibody (MAb) production in stirred and sparged bioreactors for both serum-supplemented and serum-free media. Surfactants in the culture media had a profound effect on cell growth by changing both the properties of bubbles and the qualities of foam formed. Comparable cell growth and MAb production in sparged bioreactors and in stirred and surface-aerated control cultures were observed only in Pluronic F-68 containing culture media. In media devoid of Pluronic F-68, cells became more sensitive to direct bubble aeration in the presence of antifoam agent which was used to suppress foam formation. Compared with serum-supplemented medium, more severe cell damage effects were observed in serum-free medium. In addition, serum-free medium devoid of cells was partially degraded under continuous air sparging. The mechanism of this damage effect was not clear. Pluronic F-68 provided protective effect to cells but not to the medium. A theoretical model based on the surface active properties of Pluronic F-68 was proposed to account for its protective effect on cell growth. Optimum media surfactant composition in terms of maximum cell growth and minimum foam formation was proposed for stirred and sparged animal cell bioreactor.     

Insect cell culture medium supplementation with fetal bovine serum and bovine serum albumin: effects on baculovirus adsorption and infection kinetics

The effects of insect cell culture medium supplementation with FBS were investigated. BSA was found to be the factor responsible for the increased baculovirus infection rate of FBS-supplemented cultures in a concentration-dependent form up to 25 g L(-)(1). Lower rates of baculovirus binding to cells were observed with FBS- and BSA-supplemented cultures compared with infections carried out in serum-free media. Virus attachment constants were found to depend on medium matrix composition. An efficiency factor dependent on the medium matrix composition was introduced to account for these effects, and a mathematical model was developed to describe the virus-cell interactions. It was shown that BSA acts by minimizing the nonspecific virus binding leading to an increased cell infection rate. Cell specific Porcine parvovirusvirus-like particles (PPV-VLPs) expression was unaffected by medium supplementation pointing out that BSA and/or FBS affects mainly the initial phase of the baculovirus infection cycle. Implications for process definition are discussed.     

Supplements to in vitro maturation media affect the production of bovine blastocysts and their apoptotic index but not the proportions of matured and apoptotic oocytes

The objective of this study was to compare the effect of different supplements to the basic IVM medium (TCM199) on the efficiency of cattle oocyte maturation and blastocyst production, and the incidence of apoptosis in both oocytes and blastocysts. Two protein supplements (FBS and fafBSA) and a macromolecule (PVP40) were compared in a 3 treatmentsx9 replicates design. Cumulus-oocyte complexes (COCs) aspirated from slaughterhouse ovaries were matured for 24h in TCM199 medium supplemented with 10% FBS, 6% fafBSA or 4% PVP40 (50-70 COCs in each treatment/replicate), then inseminated and cultured in vitro for 8 days. Immature and mature oocytes as well as Day 8 blastocysts were subjected to TUNEL analysis. Cleavage rate was monitored on Day 2 post-insemination (pi), whereas blastocyst yield on Day 8 pi. The composition of maturation media did not affect zygotic cleavage rate on Day 2 (on average 71.0%), however the blastocyst rate on Day 8 pi was significantly lower (P<0.001) for embryos derived from oocytes matured with PVP40 (16.0%) than for those matured with FBS (22.4%) or fafBSA (22.1%). The rate of TUNEL positive oocytes differed significantly between immature (1.4%) and mature (11.2%) oocytes (P<0.01). Supplements to maturation medium were not related to the incidence of apoptosis in mature oocytes (11.2%) and the rate of oocytes at the second metaphase stage (71.5%). Cumulus cell expansion was reduced by maturation in medium supplemented with PVP40. This macromolecule was also correlated with higher apoptotic index in blastocysts (5.8%) when compared to FBS (3.2%) and fafBSA (3.1%; P<0.001). In conclusion, lower blastocyst rate and elevated apoptotic index in embryos derived from oocytes matured with PVP40 may suggest that synthetic macromolecule provides less balanced environment for oocyte maturation and therefore should be treated with caution.     

Shear sensitivity of insect cells

Conclusions While insect cells can be easily damaged in bioreactors as a result of hydrodynamic forces, it is also relatively easy to prevent this damage. Of several possible damage mechanisms, the best understood and preventable is the attachment of cells to gas-liquid interfaces and the subjection of these attached cells to the hydro-dynamic forces and/or physical forces associated with these interfaces. For example, cells attached to gas bubbles in a bioreactor can be transported into the foam layer where they are physically removed from the cell suspension, or they can be killed when the gas bubble they are attached to ruptures at the medium-air interface at the top of the bioreactor. The easiest method to prevent this damage is through the use of specific surface active compounds, such as Pluronic F-68 or Methocel E-50 which prevent the cells from attaching to the gas-medium interface.     

Protective effect of methylcellulose and other polymers on insect cells subjected to laminar shear stress.

The relative sensitivity of two insect cell lines to laminar shear stress was determined, and the protective effect of polymers added to the growth media of two insect cell lines, Trichoplusia ni (TN-368) and Spodoptera frugiperda (SF-9), was evaluated. TN-368 and SF-9 cells were found to be equally sensitive to laminar shear stress. Methylcellulose [0.5% (w/v) Dow E4M Methocel] and dextran [4.5% (w/v)] increased the resistance of suspended cells to lysis due to laminar shear stress by factors of up to 76 and 28, respectively, compared to cells in media without additives. It was observed that the protective effect of Pluronic F-68 was concentration-dependent: 0.2% and 0.3% (w/v) F-68 increased the resistance of SF-9 cells to shear stress by factors of 15 and 42, respectively. However, increasing the concentration to 0.5% did not significantly increase the cells' resistance compared to 0.3% (w/v). F-68 at 0.2% only increased the resistance of TN-368 cells by a factor of 6. It is believed that the protection is a result of the polymer adsorbing to the cell membrane. None of the polymer additives tested had a significant effect on SF-9 or TN-368 growth rate.     

Microscopic visualization of insect cell-bubble interactions. I: Rising bubbles, air-medium interface, and the foam layer.

Through the use of microscopic, high-speed video technology, the interactions of two suspended insect cell lines, Trichoplusia ni (TN-368) and Spodoptera frugiperda (SF-9), with air and oxygen bubbles were studied. Events such as cell-bubble attachment, cell-bubble collision, cell transport into the foam layer, and trapping of cells in the foam layer are presented and discussed. Based on these observations and those in a companion paper (Chalmers, J. J.; Bavarian, F. Biotechnol. Prog. 1991, following paper in this issue) and the experimental and theoretical work of other researchers, several mechanisms of cell damage as a result of sparging are presented.