A fed-batch process using concentrated medium was evaluated for its ability to improve cell culture longevity and final monoclonal antibody (MAb) titers for two monoclonal antibody producing cell lines. It was found to result in up to 7-fold increases in final antibody titers compared to batch culture controls. Although the development cell line specific fed-batch protocols is critical to the development of cost-efficient large-scale production processes, the use of complete medium concentrates provided us with a quick and simple method for producing large quantities of antibodies in the early stages of process development, thus accelerating early work on purification process development, analytical development, biochemical characterization, and safety studies. Insights gained from the concentrated medium fed-batch approach were valuable for the development of refined, cell line specific feeding strategies yielding final MAb titers on the order of 1-2 g/L. Process development data on the effects of inhibitory growth byproducts, medium osmolarity, and the mode of nutrient feed addition on culture longevity and MAb production and information on culture metabolic behavior were successfully incorporated in the development of the optimized fed-batch protocols.
Investigations of biological effects of prolonged elevation of growth hormone in animals such as mice and rats require large amounts of mouse and rat growth hormone (GH) materials. As an alternative to scarce and expensive pituitary derived materials, both mouse and rat GH were expressed in NSO murine myeloma cells transfected with a vector containing the glutamine synthetase (GS) gene and two copies of mouse or rat GH cDNA. For optimal expression, the mouse GH vector also contained sequences for targeting integration by homologous recombination. Fed-batch culture processes for such clones were developed using a serum-free, glutamine-free medium and scaled up to 250 L production scale reactors. Concentrated solutions of proteins, amino acids and glucose were fed periodically to extend cell growth and culture lifetime, which led to an increase in the maximum viable cell concentration to 3.5×10(9) cells/L and an up to 10 fold increase in final mouse and rat rGH titers in comparison with batch cultures. For successful scale up, similar culture environmental conditions were maintained at different scales, and specific issues in large scale reactors such as balancing oxygen supply and carbon dioxide removal, were addressed. Very similar cell growth and protein productivity were obtained in the fed-batch cultures at different scales and in different production runs. The final mouse and rat rGH titers were approximately 580 and 240 mg/L, respectively. During fed-batch cultures, the cell growth stage transition was accompanied by a change in cellular metabolism. The specific glucose consumption rate decreased significantly after the transition from the growth to stationary stage, while lactate was produced in the exponential growth stage and became consumed in the stationary stage. This was roughly coincident with the beginning of ammonia and glutamate accumulation at the entry of cells into the stationary stage as the result of a reduced glutamine consumption and periodic nutrient additions.
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