The concept of quality by design (QbD), although not new, has presented implementation opportunities and challenges to both the bioprocessing industry and regulators (1,2,3,4). Tools such as design of experiments (DoE), cause and effect analysis, and multivariate analysis provide for systematic risk assessment and help identify critical quality attributes (CQAs) and critical process parameters (5,6,7). QbD is intended to ensure that manufacturing processes make products that meet predefined quality parameters. Key elements in defining such parameters (quality profile)…
Downstream Processing
Evaluating Disposable Depth Filtration Platforms for MAb Harvest Clarification
At small to medium scales, single-use technology offers significant advantages over traditional reusable (e.g., stainless steel) manufacturing technology with regard to flexibility, cost of goods, implementation timelines, and maintenance. However, process design based on disposables does create new challenges. With traditional fed-batch processes, harvest clarification is usually achieved by centrifugation followed by depth filtration. For processes based entirely on disposables, the disc-stack centrifuge needs to be replaced by filtration alone. To extend its manufacturing capabilities and capacities, Rentschler decided to…
Scaling Up Normal-Flow Microfiltration Processes
Scaling up biological processes from laboratory bench to process scale is complex and requires considering a number of factors to ensure process robustness. Due to variability among raw materials and processes, most process developers use generous safety factors to ensure that their systems are not undersized. Although that method can be reduce process risk, it is inefficient. To improve process efficiency and reduce risk, we conducted a study to identify and quantify key factors that contribute to variability…
Optimization, Robustness, and Scale-Up of MAb Purification
The biopharmaceutical industry needs faster and more efficient development of new drugs and their market introduction as well as shorter process development times for both upstream and downstream operations. It has become more commonplace to use high-throughput development techniques to save time (1). Development is also sped up by applying platform technologies based on the unsurpassed selectivity of protein A resins (2,3,4,5,6), which is the foundation for downstream processing of monoclonal antibodies (MAbs). This is the second of two articles…
Use of Blast Freezers in Vaccine Manufacture
Vaccines are powerful and cost effective prophylactic tools for protecting public health. The Global Alliance for Vaccines and Immunizations (GAVI) estimates that ~5.4 million lives are saved each year by the administration of vaccines for hepatitis B, measles, haemophilus influenza type B (hib), pertussis (whooping cough), yellow fever, and polio (1). According to the World Health Organization, seasonal influenza alone claims 250,000–500,000 lives every year globally, many of which could be prevented by more widespread vaccination with the…
Streamlining Downstream Process Development
Normal-flow filtration is used throughout downstream processes for biologics including depth, sterile, and viral filtration applications. Because of its ubiquity in large-scale biomanufacturing, using the most efficient normal-flow filter media area and type can lead to significant cost savings. To determine the most effective media type and area, developers use a scaled-down process model is used in bioprocess laboratories to minimize material requirements. Constant–flow-rate filter evaluations involve direct scale-down parameters that match manufacturing-scale process conditions. This type of evaluation can…
Rapid Process Development for Purification of a MAb
Time and flexibility are essential in purification process development for biopharmaceuticals. Easy translation of experimental ideas into process steps and insight into the effects of changes in chromatography parameters both help speed development and contribute toward achieving quality by design (QbD) objectives. An ability to scientifically design product and process characteristics that meet specific objectives is crucial. Opportunities to eliminate manually intensive steps all support an enhanced development process. A typical monoclonal antibody (MAb) purification process includes three chromatographic purification…
A Framework for Selecting and Working with a Normal-Flow Filtration Supplier
The biopharmaceutical market accounts for about 20% of the total market for pharmaceuticals, but its share continues to increase because of double-digit compound annual growth rates leading to projections that by 2014 eight of the top 10 best-selling drugs will be biologics (1). The industry faces many challenges and opportunities, as Jim Davies of Lonza Biologics explained to me: “Biomanufacturers have to contend with what is at present a dynamic technical and commercial landscape. Industry consolidation continues to occur as…
Working with a Powerful and Robust Mixed-Mode Resin for Protein Purification
Orthogonal methods for assuring robust downstream purification are critical to today’s demanding downstream process industry. Regulatory scrutiny on the immunogenic propensity of drugs has increased and broadened over the past two decades. Although immunogenicity can come from a number of sources, common concerns include host-cell proteins and aggregates. Constantly lurking in the background are other issues such as viral clearance, DNA levels, and so on. Those problems can be addressed simultaneously with the mixed-mode chromatographic support known as…
Improved Downstream Technologies Are Needed to Boost Single-Use Adoption
Greater adoption of single-use systems in biomanufacturing is going to require downstream device innovation. To get there, over a third of the biopharmaceutical industry is demanding that suppliers innovate and develop new single-use purification devices, according to BioPlan Associates, Inc.’s annual survey of biopharmaceutical manufacturing capacity (1). Such new products would create exceptional opportunities for innovators. However, calls for new, more fully integrated single-use technologies and processes will require more adventurous innovation on the part of biomanufacturers and their suppliers.…