Sampling is used extensively to monitor both behavior and quality throughout biopharmaceutical processesing (1, 2). Methods must deliver representative samples and — more important — not compromise the integrity of a given unit operation or the process of which it is part. When microorganisms, animal cells, viruses, or nonfilterable materials are involved, sampling methods must not introduce contamination (see the “Regulatory Requirements” box). For successful sampling, three methods have been used routinely over the years: steam-in-place (SIP) valves; aseptic tube…
Downstream Processing
A Risk-Based Life-Cycle Approach to Implementing Disposables for Facility Flexibility
Plastic-based, single-use, disposables has been prevalent in biotech/pharmaceutical manufacturing processes for decades. Examples of such technologies include filters, gaskets, tubing, sampling bags, carboys, and ultrafiltration/diafiltration (UF/DF) capsules. In recent years, single-use technology has made great leaps in broadening the range of options and applications available. Disposable bioprocess containers are now widely used for applications such as media/buffer preparation and storage, bioreactors and cell culture operations, in-process intermediate containers for manufacturing operations, final drug substance/product containers, and so on. Customized solutions…
The Influence of Polymer Processing on Extractables and Leachables
Polymers provide a unique set of material properties, including toughness, chemical resistance, versatility, and low cost for both multiple-use and single-use bioprocessing systems. Polymer materials are manufactured as fittings and tubing for research and development (R&D) laboratories, as containers for bulk chemical and biological storage, as filters and separation technologies for downstream processing, and as containers and bottles for drug substance storage. These components and systems are helping drug companies improve their manufacturing flexibility, reduce their operating costs and capital…
Supporting Continuous Processing with Advanced Single-Use Technologies
It has been 10 years since the US Food and Drug Administration (FDA) articulated — in its guidance for process analytical technology (PAT) — the goal of “facilitating continuous processing to improve efficiency and manage variability” (1). Since that time, regulators and industry have worked toward applying continuous processing (CP) to all facets of pharmaceutical manufacturing, including bioproduction (2, 3). Last year, the European Medicines Agency (EMA) referred to CP in its draft Guideline on Process Validation, and the FDA…
Seeding Tissue-Engineered Vascular Grafts in a Closed, Disposable Filter–Vacuum System
Tissue engineering is a multidisciplinary science that applies principles from engineering to the biological sciences to create replacement tissues from their cellular components (1). Resulting neotissues can repair or replace native tissues that are diseased, damaged, or congenitally absent. One technique that has come into widespread use is based on seeding cells onto a three-dimensional (3D) biodegradable scaffold that functions as a cell-delivery vehicle (2). Cells attach to the scaffold, which then provides space for neotissue formation and can serve…
Polishing of Monoclonal Antibodies Using Captoâ„¢ adhere ImpRes in Bind and Elute Mode
MAbs and MAb conjugates are today in great demand for use as biopharamaceuticals. As a result, more cost-effective, efficient, and flexible process purification schemes are one of the highest priorities for MAb manufacturers. In this work, results from two case studies using Capto adhere ImpRes, a multimodal anion exchanger designed for polishing, are presented. Two different MAbs were purified in bind and elute mode. The results show high yields of MAb monomers, good clearance of aggregates, HCP, and leached protein…
Single-Use Technologies in Cell Therapy
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…
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…
Managing Contamination Risk While Maintaining Quality in Cell-Therapy Manufacturing
With an increasing number of cell therapies becoming available for patient use, the need for controlled and consistent manufacturing and delivery of cell products is increasingly important. A closed cell culture process not only offers control and consistency, but may also relieve labor demands. Single-use components within a closed process also can reduce contamination risk. Closed systems with single-use platforms may reduce the risk of biological contamination and cross-contamination that could inadvertently be introduced into cell-culture processes. Such contaminants use…
Stress-Induced Antibody Aggregates
Biomanufacturing of monoclonal antibodies (MAb) involves a number of unit operations, including cell culture in a bioreactor followed by chromatography and filtration. Purification is intended to remove impurities, such as protein aggregates, but some such operations may actually generate protein aggregation (1). Table 1 summarizes potential sources of aggregate formation during biomanufacturing processes. Aggregates are multimers of native, partially denatured, or fully denatured proteins. Their presence in biological formulations can trigger detrimental immunogenic responses upon administration (2). Moreover, aggregates can…