Bioreactors

Fed-Batch Cell Culture Process Development: Implementing a Novel Nutrient Additive for a Robust, High-Titer, Scalable Process

The fed-batch culture of Chinese hamster ovary (CHO) cells has become well established as the primary method of manufacturing therapeutic recombinant protein products for various disease indications. Fed-batch process-development approaches focus on supporting high–cell-density cultures that are crucial to achieving high product titers but lead to proportionately high nutritional demands. Exhaustion of key nutrients negatively affects cell growth and ability to produce recombinant proteins. To counter that problem, concentrated feeds are added to the culture. Such feeds tend to be…

One Billion Mesenchymal Stem Cells in an Eppendorf BioBLU 5c Single-Use Bioreactor at 3.75-L Scale

For BPI’s inaugural “Ask the Expert” webcast, Ma Sha (Eppendorf’s director of technical applications) fielded questions related to his upcoming poster presentation at IBC’s Single-Use Applications for Biopharmaceutical Manufacturing in Boston this month: “One Billion Mesenchymal Stem Cells in Eppendorf BioBLU 5c Single-Use Bioreactor 3.75-L Scale”. Eppendorf R&D Labs is formerly New Brunswick Scientific, which was acquired by Eppendorf in 2007. Sha’s Presentation Our focus recently had been large-scale stem-cell applications in bioreactors. We chose to work on mesenchymal stem…

Qualification of Scale-Down Bioreactors: Validation of Process Changes in Commercial Production of Animal-Cell-Derived Products, Part 1 — Concept

Implementing continuous process improvements is increasing in priority for the biopharmaceutical industry. Such implementation can be driven by product safety, purity, and stability enhancement opportunities as well as by cost-reduction pressures. Companies invest in projects to improve product quality assurance, safety, and yield as well as production efficiency (1). Such changes may come at any process stage, from early cell-growth methods through final-product packaging improvements. Examples include growth medium optimization, purification column operation optimization, and enhanced recovery during final filling…

Cell Therapy Will Transform the Future of Medicine

The third annual IBC Cell Therapy Bioprocessing conference was held in Bethesda, MD, on 21–22 October 2013. It brought pioneers in the development of cell-based therapies together with companies that have enabling technologies, such as bioreactors, cell culture media, and advanced monitoring software. After the conference, I discussed the highlights and key themes coming out of the event with Dr. Phil Vanek, general manager of cell bioprocessing at GE Healthcare Life Sciences in Westborough, MA. Also an instructor for advanced…

Single-Use Bioreactors and Microcarriers

Cell-based therapies hold promise for treating many acute and chronic diseases (1). Optimism surrounding that therapeutic potential has driven the initiation of multiple clinical trials in pursuit of such treatments. Procedures for preparing these therapeutic agents begin with selective isolation of cells from desired tissues. That is followed by ex vivo expansion of cells of desired phenotype and functionality. Once expanded to acceptable levels, cells are stored to preserve their viability during transportation to treatment facilities. The final step in…

Mathematical Model for Production of Recombinant Antibody 14D9 By Nicotiana tabacum Cell Suspension Batch Culture

Transgenic plants are increasingly considered a competing system for producing high-value recombinant proteins for biomedical and industrial purposes at affordable costs (1). Researchers have shown that molecular farming (or biopharming) is a secure technology that is capable of rendering valuable recombinant proteins free of toxins and animal pathogens in a relatively short time (2,3,4,5,6). Scientists have also demonstrated that most recombinant antibodies produced in plants maintain their functional properties (substantial bioequivalence) as well as do those produced in mammalian cell…

Enabling Technologies

    We hear a great deal lately about the maturation of the biopharmaceutical industry — and much advancement over the past decade or so has been in business models, financing, and product pipelines. Meanwhile, regulators around the world have become more well versed in the subject matter and have adjusted their approaches to and expectations from the industry. However, the practical side of developing, characterizing, and manufacturing biotherapeutic products cannot be overlooked — nor its importance overstated. Many technological…

Enhancing Antibody Production

Increasing demand for monoclonal antibodies (MAbs) — useful as immunodiagnostic reagents in basic research applications and potential immunotherapeutics — has created a need to optimize protein production techniques. Many developers have attempted to increase MAb output from cell culture by addressing both equipment and consumables. For example, recent advances in improved bioreactor designs and bioreactor operation have increased antibody outputs by increasing cell densities and extending cell life in culture. Materials and Methods () Bioreactors can operate in batch, perfusion,…

Simpler and More Efficient Viral Vaccine Manufacturing

Human and veterinary vaccines are divided into five main categories: conjugate, toxoid, subunit, inactivated (killed), and live (attenuated) vaccines (1). The vast majority of currently licensed human and veterinary vaccines are inactivated or live (2, 3). They are produced mostly using adherent cells: primary cells such as chicken embryo fibroblasts (CEF), human diploid cells such as MRC-5, or continuous cell lines such as Vero and MDCK (4). The pioneering legacy inherited by vaccine manufacturing development has led to strategies for…

Automation of Microbioreactors

Current methodologies in genetics and microbiology enable researchers to influence metabolic pathways of microbial cells in many directions. Beside the academic interest in investigating fundamental functions in metabolic pathways, commercial production of valuable compounds by microbial hosts is state of the art. For example, such products include enzymes (lipases, proteases, phytases), therapeutic agents (insulin, antibodies), bulk chemicals (lysine, glutamate, citric acid), or the microbial cells themselves (used in brewing or milk processing), with therapeutic agents probably the fastest growing market.…