Chromatographic separations are vital both to the analysis of biological macromolecules and to their manufacturing. When properly applied, chromatography provides exquisite specificity in separating different molecules from solution based on their size, electrical charge, or other physicochemical properties. Large liquid chromatographic (LC) columns remove host-cell nucleic acids, endotoxins, viruses, and process intermediates from harvest material. Combine high-pressure liquid chromatography (HPLC) with mass spectrometric (MS) or ultraviolet–visible (UV–vis) spectroscopic detection, and you can qualify and quantify macromolecules in such…
Downstream Processing
Sterilizing-Grade Filter Sizing Based on Permeability
Sterilizing filtration renders biotherapeutics free of biocontamination. In many cases, sterilizing-grade filters also reduce bioburden or facilitate closed or aseptic processing. They are used to filter active pharmaceutical ingredients (APIs), formulated bulk, cell culture media, buffer, additives, process intermediates, and so on. Such applications are often critical for ensuring a successful batch operations. Nonetheless, a significant amount of time and resources are typically not devoted to establishing filter sizing requirements for “simple†applications such as buffer filtration. Here,…
A Decade of Filtration
Filtration is just as vital to bioprocessing as chromatography — and arguably even more so. Filters are not only used as downstream unit operations in themselves, but also in support of nearly every other step in bioprocessing. Gas or liquid filters ensure the quality of incoming air and feeds for cell culture operations, clean the circulating media in perfusion processes, aid in harvest clarification, and remove buffers from chromatographic eluate after chromatography columns. They are used in formulation…
A Decade of Processing
About halfway through our first decade in publication, we became well acquainted with a new buzzword phrase in the biopharmaceutical industry: downstream bottleneck (1). This followed on the heels of a manufacturing capacity crunch that had been forecast shortly before BPI made its debut. Thanks to herculean efforts by upstream process and cell-line engineers, that crunch didn’t pan out. In its place, however, high-titer production moved the pressure downstream. Now separation and purification engineers were tasked with handling…
Approaches to Debottlenecking and Process Optimization
Two major challenges associated with optimizing biomanufacturing operations remain unresolved. The first is variability: how to understand and improve manufacturing with significant variation in process times throughout all unit operations. The second is complexity: modern biomanufacturing facilities are complex and interconnected, with piping segments, transfer panels, and valve arrays, as well as water for injection (WFI) and other shared resource constraints. That complexity is becoming even greater with the need for process standardization and processing of higher (and…
Large-Scale, Single-Use Depth Filtration Systems
Clarifying cell culture broth is the first downstream unit operation in an elaborate sequence of steps required to purify a biological therapeutic. A combination of centrifugation, depth filtration, or tangential-flow filtration (TFF) is used for that operation. The availability of largescale, single-use, depth filtration technology in the recent years, however, has given process developers the capability to improve and simplify downstream processes. Clarification of Cell Culture Streams The main purpose of clarification is to efficiently separate…
Integrity Testing of Sterilizing-Grade Filters
Integrity testing of sterilizing-grade filters is necessary to reliably prevent damage to these sterile barriers from compromising the production of biopharmaceuticals. Documented integrity test results are essential to a manufacturing audit trail for releasing pharmaceutical products (1, 2). Accordingly, problems encountered during this testing can lead to considerable financial damages and substantial delays or even entirely prevent a production lot from being released to the market. Therefore, filter integrity testing is a critical step with high economic importance…
Retention of Highly Penetrative A. laidlawii Mycoplasma Cells
Mycoplasma are infamous for contaminating cell culture lines at rates as high as 80% (1,2,3,4,5). For biopharmaceutical processes, the inadvertent use of contaminated culture medium or medium components can lead to contamination of an aseptic process-validation media fill or cell culture medium for a bioreactor (6,7,8,9,10,11). Thoroughly testing medium components before use is generally impractical because of the large volume of material in use. Frequently, culture media cannot be autoclaved (because of the presence of heat-sensitive components or…
An Emerging Answer to the Downstream Bottleneck
Biotechnology companies have invested billions of US dollars in new manufacturing infrastructure, expanding the industry’s total mammalian cell culture production capacity from 670,000 L in 2002 to 2,550,000 L in 2010 (Figure 1) (1). This capacity expansion is estimated to have cost the industry about $20 billion (Figure 2) (1). Figure 1: Macroporous structure of Natrix chromatography media (see () Figure 1: () Figure 2: () That production capacity (and the investment it represents) is…
Key Downstream Problems Decline While Industry Continues to Demand New Technologies
Downstream problems for biomanufacturers finally appear to be lessening. Over the past six years, demand for better purification has topped the list of biomanufacturing areas in need of improvement. This year, however, it appears that purification woes — though still a hot topic — are cooling off. After seven years of measuring the impact on capacity of specific biomanufacturing operations, preliminary data from BioPlan Associates’ ninth annual survey shows that activities associated with both optimizing internal downstream processes (DSPs) and…