Allogenic Cell Therapeutics: Successfully Creating Master Cell Banks, Working Cell Banks, And Drug Product with HYPERStack Technology

The following article with Waisman Biomanufacturing originally appeared on Cell&Gene.com here.

In all cell culturing processes, a primary cell culture is necessary to establish cell lines. When preparing these cultures, cells exist in one of two forms: anchorage-dependent or suspension cells. Anchorage-dependent primary cells require attachment to a solid support to thrive and establish adherent cultures, while suspension primary cells do not need solid support (i.e., cells are suspended in the culture media).

Often, it is assumed that suspension culture is the only viable option to achieve scale-up but, in some cases (e.g., when the primary cells are of a biological type that requires adherence), adherent scale-up is a more effective choice. Many adherent platforms exist, ranging from standard cell culture flasks to fixed-bed bioreactors, and cells often must be adapted from adherent to suspension culture. In these cases,  technologies exist to bridge an adherent cell line and a suspension bioreactor — for example, microcarrier technology, wherein the beads are suspended in culture media and act as the solid support for adherent cells, which attach to the beads. However, in the case of cell therapies, current technology is not yet ideal because the microcarriers must be removed from the final product. Still, new developments emerge daily in research labs that could be translated into improvements in a GMP environment in the future.

Waisman Biomanufacturing — whose cell therapy services include work with mesenchymal stromal cells (MSCs), human embryonic stem cell (hESC) banks, and a variety of other allogeneic cell therapy lines (e.g., lung cancer cell line) for human cell therapy applications — recently scaled up capacity at its Madison, Wisc. manufacturing facility. The company ensured its expansion focused on establishing larger scale manufacturing processes for allogeneic cell therapeutics. Waisman turned to Corning HYPERStack-36 vessels — adherent cell culture platforms (Fig. 1) that support a faster and more efficient scale-up process.

Planning for a Short- and Long-Term Solution

Waisman clients’ primary challenges mirror those of any cell therapy solution provider: ensuring scalability and high yield at an acceptable cost and within the shortest possible timeline. Each client also attempts to reduce its cost of goods sold (COGS) without sacrificing quality. Larger contract manufacturing organizations (CMOs) might be able to “overpower” scale-up by simply throwing more people at a project, but more modestly sized organizations must discover novel ways to meet clients’ COGS requirements.

When Corning HYPERStack vessels became available, Waisman recognized the technology as an opportunity to increase and optimize the surface area/volumetric footprint ratio of its equipment. The aim was to increase scale without significantly increasing cost. The change from Waisman’s legacy Corning CellSTACK 10-layer vessels to HYPERStack 36-layer vessels led to “dramatic” COGS improvement. The upgrade represented a roughly 250% increase in cell production capacity for the facility, versus a 20%-25% increase in operating cost. Additionally, the change negated the need to extensively renovate the facility, acquire more incubators, or hire more people.

Thus, Waisman Biomanufacturing implemented additional capabilities for its facility and new platforms to apply to any allogeneic cell therapy product, or even to viral vectors made in adherent cell culture — all serving its growth in the long term. And, in the short term, the new HYPERStack vessels were applied to complete a client-specific application. The client was excited to collaborate with Waisman to expand its cells to the HYPERStack platform, to increase their scale while not dramatically increasing COGS, as well as to gain experience with the technology.

Great Solutions Require Exceptional Processes

To create a consistent and reliable process for cell scale-up (i.e., used to create master and working cell banks, as well as the final product, for allogenic cell therapeutics), Waisman worked toward two key goals: first, to develop and maintain a fully aseptic process. The cells can't be otherwise terminally sterilized, and Waisman wanted a process that worked on the benchtop in an ISO 7 cleanroom. Second, Waisman had to ensure cell reproducibility — consistent manufacturing from the early program stages of master and working cell bank production to final production.

Creating a fully aseptic process is crucial from a regulatory standpoint. So, the Waisman team focused on tools that allow them to manipulate multiple HYPERStack vessels at once. They designed tubing manifold systems to connect multiple HYPERStack vessels — to wash and change media, as well as to harvest the cells in a scalable and fully aseptic way (Fig. 2). Waisman was able to demonstrate through media fill runs (using bacterial growth media) that its facility can manipulate HYPERStack vessels in a way that maintains an aseptic environment, even outside the biosafety cabinet.

Challenges associated with the second goal, cell reproducibility and scalability, include accessibility. One cannot easily look inside layer 18 of 36 to examine what is going on with the cells. However, Waisman needed to have confidence cells were growing uniformly — not within just one HYPERStack, but across all 15 units. Waisman overcame this issue during process development by growing cells in parallel in both 10-layer Corning HYPERFlask vessels and 36-layer HYPERStack vessels — using the HYPERFlasks as sentinel vessels to monitor cells and then comparing total cell counts, viable cell counts, and other cell characteristics related to potency between the HYPERFlask and HYPERStack vessels. This comparison engenders confidence that process developers’ time points for changing media and for harvest are effective and scalable.

Final Thoughts

Waisman’s initial project pitch using HYPERStack technology pitted the company against very large cell therapy CMOs — companies capable of throwing people at the project to increase scale. Implementing HYPERStack vessels has allowed Waisman to be competitive, providing rapid, but also high quality, CMO services to biotech clients within difficult timelines and improving their COGS.

Ultimately, cell therapy clients own their process. When evaluating a client-specific product, like all various cell therapy applications, the technology and process applied inform the pricing. Waisman Biomanufacturing’s pricing, for example, is based on production capacity — running 15 36-layer HYPERStack vessels for a process, while making assumptions about harvest density based on either early client data or just general assumptions, to provide clients a price per deliverable. That said, it warrants mention that harvest density is based on the process scale Waisman is able to achieve, rather than an exact cell deliverable. Ultimately, a client moving later into clinical development would gather its batch records and other data, building their own facility to continue or applying lessons learned at a different CMO facility.

Just as Corning Life Sciences was able to work with Waisman Biomanufacturing, providing platforms to optimize and scale up cells for cell therapy, they can help other CDMOs and CMOs meet their production capacity and COGS needs. To learn more, visit www.corning.com/lifesciences.

About The Contributor

Brian Dattilo, Ph.D., is the Director of Business Development at Waisman Biomanufacturing. Dattilo earned his Ph.D. in biochemistry from Vanderbilt University, where he focused on recombinant protein production, purification, and analytical characterization. Prior to Waisman, Dattilo served as a program manager at the Biomedical Advanced Research and Development Authority (BARDA), where he was responsible for a multi-million-dollar development budget supporting novel platform technologies and their application to vaccine, biological therapeutic, and diagnostic development for pandemic influenza and biodefense applications. Since joining WB in 2012, he has led client interaction, technical product development plan development, and project budgeting and cost estimation, as well as built business cases for new platform investment.

About Corning Life Sciences

Corning Life Sciences is a global, leading manufacturer of products for growing cells, bioprocess manufacturing, liquid handling, benchtop equipment, and glass. Corning strives to improve efficiencies and develop solutions that enable researchers to harness the power of cells to create breakthrough innovations. Corning supports research for several application areas including core cell culture, bioprocess, cancer research, primary and stem cells, drug screening, cell and gene therapy, disease modeling, lab automation, and more. Learn more at www.corning.com/lifesciences.

About Waisman Biomanufacturing

Waisman’s team of cell culture specialists have a broad range of experience that enables us to optimize the culture parameters unique to each product cell line. Working in close contact with each client, we develop a cell culture process and cell banking program that meets CGMP/ICH requirements. Our facility houses five cell therapy suites that are specifically designed for the cultivation of mammalian cells for use in cell therapy applications including production of master and working cell banks for biologics production and cell and gene therapies. To learn more, visit us at www.gmpbio.org.