Single-use technologies (SUTs) are tools that can be used in producing cell therapies and personalized medicines. Such products must meet specific requirements because of the way they are used. To meet those criteria, the cell therapy industry simply has no alternatives to single-use systems. SUT applications are rapidly changing. Traditional uses for single-use systems in cell therapy include processing in clinical settings (e.g., blood bags, transfer sets) and research and development (e.g., T-flasks, pipettes). Although such applications continue, the commercialization…
Cell Line Development
A Powerful Pairing
Biological product and process characterization are not new to this quality by design (QbD) and process analytical technology (PAT) era. In the 1990s we saw the FDA introduce the concept of well-characterized biologics: an acknowledgment that analytical technology had advanced to the point where the bioprocess did not necessarily (or not fully, anyway) define a biopharmaceutical product. That ultimately led to the regulation of some types of products within the United States moving from the purview of FDA’s Center for…
Automation of Cell Therapy Biomanufacturing
Biomanufacturing automation is an established mission-critical step in the commercialization pathway for conventional therapeutics, including small molecules and monoclonal antibodies (MAbs) (1). The prospect of a potential biologic progressing into late-stage clinical trials without a robust biomanufacturing strategy to support at least pilot-plant scale bioprocessing is simply unthinkable. Conversely, the cell therapy industry (or at least a significant proportion of it) regard this as a trend that is unlikely to be mirrored as the industry develops. The aim of this…
Characterization of Human Mesenchymal Stem Cells
Human mesenchymal stem cells (hMSCs) are a self-renewing population of adherent, multipotent progenitor cells that can differentiate into several lineages. The current definition of MSCs includes adherence to standard tissue culture plastic ware, expression of various surface antigens, and multilineage in vitro differentiation potential (osteogenic, chondrogenic, and adipogenic). hMSCs hold great promise as therapeutic agents because of their potential ability to replace damaged tissue and their immunomodulatory properties. Consequently, many clinical trials using hMSCs are currently under way in a…
Implementation of Quality By Design in Vaccine Development
At the IBC Third Annual International Forum on Vaccine Production, I presented an outline of “Best Practices for Quality by Design (QbD) in Biological Products and How to Implement in Vaccines.” It covered process development and QbD principles, best practices used in biologics, how QbD fits in with process validation, how it applies to vaccines, and some thoughts on the potential for seasonal vaccines. Shifts in Process Development Classic process development (as practiced in the early days) generally involved rudimentary…
Manufacturing Culture
Life sciences company leaders need to put the right people, processes, and technologies in place to create evolutionary cultures. Such cultures would embrace advanced manufacturing process intelligence and reap related business benefits. Since the late 1990s, my software company has helped biomanufacturers improve their process understanding. In that time, we’ve seen regulatory drivers such as quality by design (QbD) and process analytical technology (PAT) guidances call for improved manufacturing process performance through better process understanding and optimization. We define process…
Antibodies, Bioassays, and Cells
It’s no surprise that immunochemistry forms a broad and solid basis of biopharmaceutical analytical laboratory work. Immunochemicals include antibiotics and antigens, nucleic acids and nucleotides, enzymes, lipids, antioxidants, probes and dyes, and proteins and peptides. Available from companies such as Advanced Immunochemical, Immundiagnostik, Lampire Biological Laboratories, and Rockland Antibodies and Assays, their many uses include antibody isotyping and fragmentation. Adjuvants, buffers, assay kits, target biomolecules, and phage-display systems support those applications. Because background and off-target effects complicate the study of…
Protein Scaffolds
The recent success of monoclonal antibodies (MAbs) as therapeutic agents to treat cancer, multiple sclerosis, rheumatoid arthritis, and other chronic inflammatory and autoimmune disorders (Table 1) has catapulted these once difficult-to-develop molecules to the forefront of modern molecular medicine (1, 2). The size of the global MAb market in 2008 was valued at almost US$28 billion. Industry analysts predict that the size of the MAb market will grow to almost $68 billion by 2015, with the largest growth occurring in…
Biophysical Analysis of Living Cells
Adecades-old technology is finally emerging from clinical laboratories and demonstrating its utility in drug discovery and development. Cell therapy researchers bring their laboratory experiences with them as their science is commercialized. And as biopharmaceutical production engineers incorporate quality by design (QbD) and process analytical technology (PAT) into their work, they find that a method for monitoring the state and distribution of living cells can help build valuable upstream process knowledge. In flow cytometry, cells are suspended in fluid to flow…
A High-Yielding, CHO-K1–Based Transient Transfection System
Biotherapeutics have emerged as effective treatments for many diseases. It’s estimated that every year hundreds of new biotherapeutic candidates enter development (1). Stable transfection of host cells to establish high-producing cell lines is the approved method for generating clinical-grade recombinant biologics. However, biotechnology companies needing to speed up their developmental timelines are increasingly relying on material generated using transient transfection (1, 2). Unlike stable gene expression (SGE) that requires several months of laboratory and process work, transient gene expression (TGE)…