Single-use technology has arguably been the biggest “story” of the past 10 years in bioprocessing. And for many people, implementation of disposable elements began soon after the turn of the century with a bioreactor (1, 2), first developed by Wave Biotech in 1996, now a mainstay of many upstream process development laboratories and sold by GE Healthcare. BPI identified the significance of such technologies early on, making them the subject of a supplement in its second year. By the fourth…
Analytical
Bioreactor Design and Bioprocess Controls for Industrialized Cell Processing
It’s official: The “Age of Cell Therapy” has arrived. A robust pipeline of cell therapies, with increasing numbers of both early- and late-stage clinical trials as well as FDA-approved commercial products that have entered the market already, strongly indicates that the cell therapy industry is poised to emerge as a distinct healthcare sector (1). Renewed investor interest and recent activity among major pharmaceutical companies suggest that this industry will rapidly develop the capability and capacity to be a highly competitive,…
A Decade of Bioreactor and Upstream Technologies
A high-quality product begins with efficient upstream process equipment. Ten years ago, manufacturers were still warming up to single-use bioreactors, which were mainly rocking-bag–based solutions. The benefits relating to cleaning and validation were clear, but their use as bioreactor vessels was still new, and stainless steel systems up to 20,000 L in scale were still needed. Today’s facilities are a hybrid of sophisticated single-use components and stainless steel equipment, the mechanisms of both having undergone improvement during the past decade.…
A Decade of Microbial Fermentation
Microorganisms play a vital role in modern life — with applications ranging from wine fermentation to biofuel production to solutions for complex mathematical problems (1). During the past decade, microbial fermentation for protein production reached a higher level of sophistication and wider adoption. When BPI was first published in 2003, the physical and biological characteristics of many microbial cells and the attributes of their fermentation processes were well known. Nonetheless, the economic environment at that time created immense pressure on…
A Decade of Animal Cell Culture
Eukaryotic cells are fragile and finicky, requiring very specific culture conditions and nutrients to survive, grow, and be productive in an ex vivo environment. Even so, they have become vital to the biopharmaceutical industry’s ability to make complex biological products — overtaking yeast as a production system around 1990 and surpassing bacteria in the number of associated product approvals five years later (1). Since then, they have become even more useful, expanding their reach into the vaccine world. Mammalian cell…
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 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…
A Decade of Harvesting Methods
The preliminary separation of a protein of interest from a reactor “soup†of process impurities (e.g., cell debris, colloids, lipids) is the first step in a downstream process. It is also a primary step that introduces a significant risk of product degradation, bioburden concerns, or process errors, especially if a harvest method is not a good “fit†with a newly designed bioreactor (e.g., single-use) or fermentation vessel. In 2003, BPI’s first year, industry concerns revolved around potential capacity…
A Decade of Process Development
Our “manufacturing †theme could be considered a sort of catch-all, encompassing much of what BioProcess International covers. You could argue that “the whole development process†is all about manufacturing biotherapeutics. But we instead consider this “pillar†of bioprocessing to include everything that isn’t strictly “upstream†(production) or “downstream†(processing) of biomolecules. Facility and supply-chain isssues come into play here, as do formulation and fill–finish (and of course, outsourcing). We discuss quality systems and their associated analytics in…
A Decade of Characterization
Over the past 10 years, the biopharmaceutical industry has placed increasing pressure on analytical laboratories, whose work is more important to the success of biotherapeutic products than ever before. Nearly concomitant with the appearance of BPI on the scene, the US Food and Drug Administration put forth its final report on the 21st century good manufacturing practice initiative, which in changing how regulators would review product applications, changed how companies must approach them (1). The guiding principles —…