At the onset of modern-day biotechnology, products typically fell into two distinct categories, the traditional high volume, low value products (e.g. beer and industrial enzymes) that had come to characterize the biotechnology industry, and low volume, high cost products. Recombinant proteins, the result of technological advances in molecular biology, have come to typify these latter products. Recombinant protein therapeutics have been hugely successful, potentially outstripping production capacity and continue to drive much of the biotechnology. Meanwhile, many recombinant proteins, those characterized as research tools and reagents, are governed by a price-volume relationship typical of industrial enzymes. In a competitive environment, they are fast becoming commodities — price sensitive, packaged as kits, coupled to instrumentation, and relying on heavy marketing and brand recognition. Ominously, the advantage protein therapeutics have enjoyed with patent protection and regulatory constraints on production is being threatened as patents expire and competition from generics increases…
Tag: <span>scale-up</span>
Bioreactor productivities are highly dependent on the process used to cultivate mammalian cells. These productivities directly affect the manufacturing plant capacity, and thereby the economics of production of monoclonal antibodies (MAbs). Historically, companies have chosen bioreactor process strategies that emphasize simplicity of scale-up at the expense of productivity, and conducted manufacturing using well-characterized and relatively straightforward batch processes. Such processes have successfully produced small or moderate quantities (ranging from ~100 g to ~ 1 kg per lot) of the desired antibody. Given the anticipated demand for large-scale quantities of MAbs (and the high stakes for the companies investing in these new biological entities), it is worthwhile to revisit these past selection strategies and see if — and under what conditions — they remain optimal today…
The revolution in biotechnology has led to 133 biotechnology-derived medicines being approved by 2001 with sales of $22 billion. This is less than 10 percent of today’s total pharmaceutical market, but it is a rapidly growing sector. Biologics are predicted to grow to nearly $50 billion by 2008. Marketed biopharmaceuticals include several blockbuster products with multibillion-dollar sales. In recent years, biotechnology-derived therapies represented 10 percent to 20 percent of all new approved molecular entities and hundreds more are in development, including nearly 200 proteins in late-stage trials. Microbial and mammalian expression systems are typically used to produce biotherapeutic proteins (many companies are also working on transgenic expression systems). Microbial cultures (typically, Escherichia coli or yeast) are used to produce smaller, less-complex proteins or those where specific modifications, especially glycosolation, are not required…
The characterization of a batch cell culture process to produce a monoclonal antibody from a GS-NS0 mouse myeloma cell line is described. Productivity and cellular metabolism were monitored during scale-up to both characterize the process and aid in assessing cell culture stability. During fermentation scale-up studies, it was found that as culture generation number increased, productivity declined. In both flask and bioreactor cultures, declining production started abruptly at approximately generation 60. In this study, we assessed whether the decline in productivity was due to genetic instability of the cell line, which resulted in the generation of a non-producer sub-population, or a shift to a less productive state of cellular metabolism…