Growth of NS0 cells in protein-free, chemically defined medium

Many hybridoma and recombinant myeloma cell lines have been successfully adapted to growth in protein-free media. Compared with serum-supplemented media, use of protein-free media promotes superior cell growth and protein expression and facilitates downstream purification of the expressed product. Owing to its sterol auxotrophy, the NS0 myeloma is normally grown in either a serum-supplemented medium or a serum-free medium supplemented with an animal-derived lipoprotein. CD Hybridoma Medium (a protein-free, chemically defined formulation) grows many cell lines that do not exhibit lipid dependence, but this medium does not support growth of NS0 cells without further lipid supplementation. We tested several commercially available lipid supplements in CD Hybridoma Medium, including bovine EX-CYTE VLE. None of the tested supplements supported long-term growth of NS0 cells in CD Hybridoma Medium. Sustained long-term growth of NS0 cells was achieved in CD Hybridoma Medium supplemented with various animal- or plant-derived lipids complexed with cyclodextrin. NS0 cells adapted to CD Hybridoma Medium supplemented with cyclodextrin-lipid complex reached peak cell densities that were more than double those observed in serum-supplemented medium and were cultured for more than 15 passages. These cultures were also successfully cryopreserved and recovered in this defined medium. Through the use of cyclodextrin-based additives to CD Hybridoma Medium, it is possible to solubilize significant quantities of sterols and other lipids and to maintain a protein-free, chemically defined cultivation environment for NS0 cells. The culture system can be kept entirely free of animal-derived components if the supplement is made with plant-derived or synthetic lipids.     

Iron (III) citrate inhibits polyethylenimine-mediated transient transfection of Chinese hamster ovary cells in serum-free medium

Recent advances in transient transfection protocols using polyethylenimine (PEI) as a transfection reagent have led to the development of economical methods that provide yields sufficient for industrial production of proteins for many preclinical needs. There are many variables that can be optimized to improve protein expression in transient transfection, and one of the most critical is the medium in which the cells are grown. While transfection with PEI works well in media containing serum, the biopharmaceutical industry is moving away from animal-derived components in media. A number of serum-free media have been found to allow transient transfection, but many others do not for reasons that are not clear. Thus, knowledge of the components of serum-free media that can cause inhibition of PEI-mediated transient transfection would be useful for media development. In this study, an analysis was performed of various components of a serum-free medium used for Chinese hamster ovary cells in which PEI-mediated transient transfection was inhibited. We found that an iron supplement added to the medium was responsible for the inhibition. Further investigation showed that iron (III) citrate, a common iron chelator found in serum-free medium, was the specific component that caused the effect. Further, we showed that inhibition of transient transfection was caused by iron (III) citrate specifically, rather than citrate or iron alone. Finally, we showed that various iron chelators in serum-free media other than iron (III) citrate do not inhibit antibody expression.     

In vitro development of Cryptosporidium parvum in serum-free media

AIM: To compare commercially available serum-free media with common, standard, growth medium for their ability to support growth of Cryptosporidium parvum in HCT-8 cell cultures. METHODS AND RESULTS: Twelve serum-free media formulations with or without additional supplements were tested against a standard growth medium containing 2% FBS in HCT-8 cell cultures. After a 48-h incubation period, the level of parasite development was determined by ELISA. The extent of development in the serum-free media was determined as a percentage of infections compared with those obtained using a standard growth medium. CONCLUSIONS: Several of the serum-free media formulations, which included MDCK, UltraMDCK, PC-1, UltraCHO and UltraCulture, compared favourably with a traditional, standard growth medium. Moreover, increasing FBS concentrations to 10% actually resulted in an overall decrease in development in many cultures. SIGNIFICANCE AND IMPACT OF THE STUDY: Several serum-free medium formulations are available which allow development of C. parvumin vitro at levels comparable with standard media employing FBS. These serum-free media are particularly useful for applications, which may require a more defined medium without the presence of FBS. Moreover, the elimination of FBS as a variable allows investigators the ability to more closely regulate their experimental systems when growing C. parvum in cell cultures.     

Media for cultivation of animal cells: an overview

The increasing interest in products from animal cells has caused an extensive research effort towards development of media for cell cultivation.The basic components in the media used for cultivation of animal cells vary depending upon the characters of the cells and the cultivation method. Basic components consist of an energy source, nitrogen source, vitamins, fats and fatty soluble components, inorganic salts, nucleic acid precursors, antibiotics, oxygen, pH buffering systems, hormones, growth factors and serum. Extensive efforts are directed towards developing serum-free or chemically defined media. Among the serum substitutes is a long list of hormones and growth factors.     

Proteome analysis of virus–host cell interaction: rabies virus replication in Vero cells in two different media

The use of Vero cells for rabies vaccine production was recommended from the WHO in 2005. A controlled production process is necessary to reduce the risk of contaminants in the product. One step towards this is to turn away from animal-derived components (e.g. serum, trypsin, bovine serum albumin) and face a production process in animal component-free medium. In this study, a proteomic approach was applied, using 2-D differential gel electrophoresis and mass spectrometry to compare rabies virus propagation in Vero cells under different cultivation conditions in microcarrier culture. Protein alterations were investigated for uninfected and infected Vero cells over a time span from 1 to 8 days post-infection in two different types of media (serum-free versus serum-containing media). For mock-infected cells, proteins involved in stress response, redox status, protease activity or glycolysis, and protein components in the endoplasmic reticulum were found to be differentially expressed comparing both cultivation media at all sampling points. For virus-infected cells, additionally changes in protein expression involved in general cell regulation and in calcium homeostasis were identified under both cultivation conditions. The fact that neither of these additional proteins was identified for cells during mock infection, but similar protein expression changes were found for both systems during virus propagation, indicates for a specific response of the Vero cell proteome on rabies virus infection.     

Micro-quantitation of lipids in serum-free cell culture media: a critical aspect is the minimization of interference from medium components and chemical reagents

Lipids (fatty acids) at a concentration range of 10-100 microg/L are essential components included in most serum-free cell culture medium formulations. A gas chromatography/mass spectrometry (GC/MS) method for the micro-quantitation of lipids, determined as fatty acid methyl esters (FAMEs), in complex serum-free cell culture media was developed. The interference of derivatizing reagents, extraction solvents and medium additives in the micro-quantitation of lipids was also examined. The results show that the concentration of fatty acids such as palmitic and stearic acids detected in derivatizing reagents or extraction solvents was in the range of 10-230 microg/L. Tween-80, a surfactant and medium additive, produced nearly 20 FAMEs alone when methylated using a derivatizing agent. Moreover, the surfactant Pluronic F-68, a medium additive, interfered in the FAME recovery. Procedures, which include use of low volumetric ratio of reagent to medium and precipitation of the above surfactants, were developed to minimize background FAMEs to levels which do not significantly affect the quantitation of medium lipids and to diminish the interference caused by Pluronic F-68. Fatty acid concentrations in several complex serum-free culture media were quantitated by this method and were very close to the values indicated in their formulations.     

Quantitation of interaction of lipids with polymer surfaces in cell culture

As cell culture medium development efforts have progressed towards leaner, serum-free, and chemically defined formulations, it has become increasingly important to ensure that the appropriate concentrations of all nutrients are maintained and delivered at point of use. In light of concurrent efforts to progress to disposable polymeric storage and culture platforms, the characterization and control of medium component interactions with container surfaces can be a key issue in ensuring consistent delivery of these medium formulations. These studies characterize the interactions of lipids with culture surfaces typically encountered in the bioprocess industry using model systems. The extent and kinetics of lipid association with polymeric surfaces were determined using radio-labeled linoleic acid and cholesterol. The effect of methyl-beta-cyclodextrin, a component commonly used to solubilize lipids in culture media, on association kinetics was also examined. In addition, loss of lipids across a sterilizing membrane filter was quantified. We find that there is potential for significant loss of hydrophobic components due to non-specific binding to surfaces at timescales relevant to a typical cell culture process. The extent of loss is dependent on the nature of the hydrophobic component as well as the type of surface. These studies highlight the potential of the extracellular environment to modify medium composition and also emphasize the importance of medium formulation strategies, including those used in the delivery of hydrophobic components. It is noted, however, that the level of loss is very dependent on the specific system including the composition of the culture medium used.     

Electrophysiological and morphological characterization of rat embryonic motoneurons in a defined system

In an attempt to integrate biological components with silicon-based devices and systems, artificial silane surfaces have been successfully used to grow motoneurons in a defined environment. In this study we characterized the morphology and electrophysiology of purified rat embryonic (E14) motoneurons grown on a self-assembled monolayer (SAM) of N-1[3-(trimethoxysilyl)propyl]diethylenetriamine (DETA) versus that on ornithine/laminin surfaces in serum-free media. On DETA motoneurons were flat and grew more processes, whereas on ornithine/laminin they tended to aggregate. The membrane time constant, a characteristic associated with electrotonic compactness, was significantly longer for motoneurons grown on DETA. Other electrophysiological parameters were similar for the motoneurons on the different surfaces. This is the first study where purified ventral horn motoneurons were cultured in a completely defined (nonbiological surface, serum-free) environment.     

Current Status for High Titre Poxvirus Stock Preparation in CEF Under Serum-Free Medium Conditions: Implication for Vaccine Development

In light of the recent detection of BSE in North America and its endemic nature in other regions of the world, there is a real need to employ cell culture conditions that do not require any animal-derived material. Here we report the use of an ultra-low protein serum-free medium (VP-SFM, Invitrogen) for the amplification of poxviruses in primary chicken embryo fibroblasts (CEF). We compared the amplification of four different poxviruses (canarypox, modified Ankara Virus (MVA), vaccinia virus strain Copenhagen and myxoma strain Lausanne) in three different media: DMEM 10%, DMEM 2% and serum-free medium VP-SFM. VP-SFM is a serum-free, ultra-low protein medium containing no proteins or peptides of human or animal origin designed to support the replication of viruses and the production of recombinant proteins and monoclonal antibodies. Our results show that high titre poxvirus stocks can be prepared in VP-SFM equivalent to that prepared in serum containing medium.     

Serum-free media in hybridoma culture and monoclonal antibody production

The replacement of serum in hybridoma cultures is considered. The focus is on the effects of serum-free media on hybridoma growth and monoclonal antibody secretion. Comparative literature data with serum supplemented cultures are discussed with an analysis of serum-free formulations and selection rules for the serum-free ingredients. In general, serum-free media which are "lipid rich" can sustain cell growth rates approaching that of serum supplemented cultures. Specific antibody secretion rate, however, is usually higher in serum-free media, irrespective of the lipid content.     

Nutrient optimization for high density biological production applications

Conclusion At the 1989 annual meeting of the U.S. Tissue Culture Associations, Ricahrd am, a leading investigator in the serum-free nutrient requirements of cultured cells, commented on the process of medium development. He noted that a survey of major media manufacturers revealed that, among the top selling mammalian cell culture media formulations, most were nearly thirty years old.This commentary is noteworthy considering the tremendous changes in cell culture understanding and derived applications which have emerged over these three decades. Fastidious cell types relatively unknown to investigators of the 1950s and 1960s are now being cultivated in defined, serum-free environments. Culture environments range from limiting dilution clonal recoveries to maintenance cultures approaching tissue densities. While research applications continue to predominate, applications of cell culture have expanded to the engineered production of biopharmaceuticals, to replacement of animal models for toxicology testing, and to the preservation, activation and expansion of human cells, tissues and organs.It is likely that future nutrient medium development will be predicated upon the design of a minimal number of defined formulations of relatively generic utility to a broad class of cell types. Analytical techniques derived from those described herein will be exploited in the user laboratory and in collaboration with the supplier to optimize the nutrient composition for the desired biological response.     

Decreasing variability in your cell culture

Culturing mammalian cells has not significantly changed in almost 50 years. Typically, a synthetic basal medium is chosen to meet the environmental and nutritional requirements of a given cell line. Components, such as amino acids, vitamins, inorganic salts, and a carbon source such as glucose are commonly found in the classical basal media formulation. These basal formulations normally will not support cell growth alone, but must be further supplemented with animal serum, usually fetal bovine serum (FBS) at a concentration of 5-20%. Recent advances in serum-free and chemically defined media formulations have provided cell culturists with options. When considering FDA regulations and potential risks to human health when manufacturing biologics or considering cell therapies, eliminating serum is of paramount concern. For a large majority of researchers however, using classical media with serum builds on previous generations of research and makes cell culture easier to perform.     

High cell density perfusion culture of hybridoma cells recycling high molecular weight components

We have developed a high cell density and high product concentration culture system recycling high molecular weight components. The production of monoclonal antibodies in high concentration was performed by this culture system with mouse human hybridoma H2 and V6 cells in serum-free defined media.The concentration of IgG after 48 days culture of H2 cells in ITES-eRDF reached 2 mg/ml and the purity of IgG in culture fluid was 61%. In addition, high molecular weight components in serum-free media, such as transferrin or BSA, could be reduced to 5% of the original concentration.     

Investigation of reduced serum and serum-free media for the cultivation of insect cells (Bm5) and the production of baculovirus (BmNPV)

An experimental study has been carried out to investigate the effectivenes of several reduced serum and serum-free media for the cultivation of an ovarian cell line, Bm5, of the lepidopteran insect Bombyx mori. Bm5 cell were successfully adapted to grow in a medium containing 5% serum and a serum-free medium (EX-CELL 400). On the other hand, this cell line could not be adapted to grow in several other media suggested in the literature, including IPL-41 + 2% fetal bovine serum (FBS), SF-900, and a serum-free medium (ISFM). Furthermore, a comparative study was conducted to determine the production levels of B. mori nuclear polyhedrosis virus (BmNPV) in Bm5 cells cultured in three different medium formulations. The production levels of BmNPV in adapted Bm5 cells grown in a 5% serum-supplemented medium and a serum-free medium (EX-CELL 400) were comparable to those obtained in Bm5 cells grown 10% serum-supplemented medium. (c) 1992 John Wiley & Sons, Inc.     

Characterization of different cell culture media for expression of recombinant antibodies in mammalian cells: Presence of contaminating bovine antibodies

Several new cell culture media designed specifically for the expression of recombinant antibodies in Chinese hamster ovary (CHO) cells were investigated for the presence of bovine IgG. Three serum-free media, three protein-free (animal component free) media, as well as one chemically defined medium were included in the study. Employing a combination of affinity chromatography (Protein G or A columns), SDS-PAGE analysis, and peptide mass fingerprinting, two of the serum-free media were found to contain bovine IgG in the range of approximately 0.5 mg/L. The other five media did not contain detectable levels of contaminating Protein A or G-binding proteins such as bovine IgG.     

Uniform stable-isotope labeling in mammalian cells: formulation of a cost-effective culture medium

Uniform stable-isotope labeling of mammalian cells is achieved via a novel formulation of a serum-free cell culture medium that is based on stable-isotope-labeled autolysates and lipid extracts of various microbiological origin. Yeast autolysates allow complete replacement of individual amino acids and organic acids in a chemically defined medium (DMEM/F12), enabling a cost-effective formulation of a stable-isotope-labeled culture medium for mammalian cells. In addition, biomass-derived hydrolysates, autolysates, and lipid extracts of various classes of algae were explored as cell culture components, both separately and in combination with yeast autolysates. Optimal autolysate concentrations were established. Such novel medium formulations were tested on mammalian cell lines, often used for recombinant protein production, i.e., Chinese hamster ovary (CHO) and human embryonic kidney (HEK 293). Special attention was paid to the adaptation of these mammalian cell lines to serum-free media. Formulation of the novel proprietary cell culture medium PLIm, based on yeastolates instead of individual amino acids and organic acids, allows a four- to eightfold cost reduction for ¹⁵N and ¹³C,¹⁵N stable-isotope-labeling, respectively, in CHO cells and a three- to sixfold cost reduction in HEK 293 cells. A high level of stable-isotope enrichment of mammalian cells (>90%) was achieved within four passages by complete replacement of carbon and nitrogen sources in the medium with their stable-isotope-labeled analogs. These conditions can be used to more cost-effectively produce labeled recombinant proteins in mammalian cells.     

Improvement of mammalian cell culture performance through surfactant enabled concentrated feed media

The design of basal and feed media in mammalian cell culture is paramount towards ensuring acceptable upstream process performance in various operation modes, especially fed‐batch culture. Mammalian cell culture media designs have evolved from the classical formulations designed by Eagle and Ham, to today's formulations designed from continuous improvement and statistical frameworks. Feed media is especially important for ensuring robust cell growth, productivity, and ensuring the product quality of recombinant therapeutics are within acceptable ranges. Numerous studies have highlighted the benefit of various media designs, supplements, and feed addition strategies towards the resulting cell culture process. In this work we highlight the use of a top‐down level approach towards feed media design enabled by the use of select surfactants for the targeted enrichment of a chemically defined feed media. The use of the enriched media was able to improve product titers at g/L levels, without adversely impacting the growth of multiple Chinese Hamster Ovary cell lines or the product quality of multiple recombinant antibodies. © 2013 American Institute of Chemical Engineers Biotechnol. Prog., 29:1023–1033, 2013     

Media formulation options and manufacturing process controls to safeguard against introduction of animal origin contaminants in animal cell culture

Technical limitations and evolution of therapeuticapplications for cell culture-derived products haveaccelerated elimination of animal-derived constituentsto minimize inadvertent introduction of adventitiousviral or prion agents. Practical considerationsdemand adequate emphasis both on design of theserum-free/protein-free culture environment and onnutrient media manufacturing process controls. Protein components may be acceptable, given adequateattention to synthetic process, sourcing (e.g.,geographic location and endemicity, species andtissue/organ) and validated treatment method. Variousoptions exist for re-engineering of traditionalserum-free formulations (containing insulin,transferrin and other protein factors) withnon-protein substitutes. Caution must also beexercised with sourcing of non-protein additives,particularly amino acids and lipids, to avoidintroducing adventitious contaminants. Simpleguidelines facilitate adaptation, cryopreservation andrecovery of many cell types within a protein-freeculture environment. Scrupulous maintenance offacility and equipment and monitoring of processwater, air handling systems and technical personnelare required to ensure that approved raw materials arecorrectly formulated and dispensed. Validatedsanitization processes provide additional assuranceagainst cross-contamination from previous batches ina multi-use facility.     

Serum-free media for cultures of primitive and mature hematopoietic cells

The in vitro culture of human hematopoietic cells has many research and therapeutic applications. Traditionally, human hematopoietic cultures have been conducted using serum-containing media. The disadvantages inherent in the use of serum could be eliminated by the use of serum-free media. In this review, we summarize and discuss the current status of serum-free media for both mature and immature human hematopoietic cells. The mature hematopoietic cells discussed are of lymphoid (e.g., lymphokine activated killer cells and tumor infiltrating lymphocytes) and myeloid origin (e.g., monocytes/macrophages). The cultures of immature hematopoietic cells discussed are clonogenic and long-term cultures. In addition, we briefly review the types of human hematopoietic cells, their clinical applications, and the basic strategies and components used to formulate serum-free media, Finally, we outline future requirements and directions in the development of serum-free media for primitive hematopoietic cells.     

Identification of growth and attachment factors for the serum-free isolation and expansion of human mesenchymal stromal cells

Background aimsEx vivo propagation of sparse populations of human mesenchymal stromal cells (hMSC) is critical for generating numbers sufficient for therapeutic applications. hMSC culture media have typically been supplemented with animal serum and, recently, human-sourced materials. However, these supplements are ill-defined and, thus, undesirable for clinical and research applications. Previously reported efforts to develop defined media for hMSC culture only resulted in slow or limited proliferation, and were unsuccessful in expanding these cells from primary cultures. Therefore a major step forward would be the identification of defined, serum-free culture conditions capable of supporting both the isolation and rapid expansion of hMSC.MethodsUsing classical approaches of medium development, we were able to identify a set of growth and attachment factors that allowed the serum-free isolation and expansion of hMSC from bone marrow.ResultsHeparin, selenium and platelet-derived growth factor (PDGF)-BB were found to be inhibitory for the growth of hMSC, whereas basic fibroblast growth factor (bFGF) was critical and worked synergistically with transforming growth factor (TGF)-β1 to allow significant cell expansion. Ascorbic acid, hydrocortisone and fetuin were also found to be important growth and attachment factors that, in conjunction with substrate-coating proteins, allowed the isolation of hMSC from primary culture and their subsequent expansion.ConclusionsWe report a defined medium formulation (PPRF-msc6), consisting of key recombinant and serum-derived components, for the rapid isolation and expansion of hMSC in the absence of serum. This work represents an important step forward for achieving an ideal, completely defined synthetic medium composition for the safe use of hMSC in clinical settings.