Novel Workflow for Activation and Expansion of T Cells Using Microbubble Technology

Chimeric antigen receptor (CAR) T cell therapy was developed to address the significant hurdles to cancer treatment. In the US, one in four deaths is due to cancer, with treatment costs totaling over $200 billion a year. Traditional treatments, such as chemotherapy and radiation therapy have serious...

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Bibliographic Details
Published in:The Journal of immunology (1950) 2023-05, Vol.210 (1_Supplement), p.249-249.16
Main Authors: Ellis, Jason S, Barrett, Crisha B, Snow, Tiffany, Roussey, Jon, Carey, Maureen, Ku, Chia, Grimley, Edward, Wegner, Casey J, McNaughton, Brandon H
Format: Article
Language:English
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Summary:Chimeric antigen receptor (CAR) T cell therapy was developed to address the significant hurdles to cancer treatment. In the US, one in four deaths is due to cancer, with treatment costs totaling over $200 billion a year. Traditional treatments, such as chemotherapy and radiation therapy have serious harmful side effects, often with limited success. Despite the immense hurdles to producing a cost effective, efficient, and scalable workflow for manufacturing CAR T cells, thousands s of CAR T cell therapy clinical trials have been initiated around the world. Traditional CAR T cell workflows often result in T cell exhaustion, limiting the effectiveness of the cells produced. At Akadeum, we set out to create a simple workflow to improve researchers’ ability to develop custom cell therapies. Using Akadeum’s microbubbles, we developed a process that combines selection, activation, and expansion into a single workflow. Because of the natural buoyancy of the microbubbles, activation and expansion take place at the top of the culture. As the T cells divide, daughter cells fall to the bottom of the well away from the activation signals. This prevents overstimulation and the resulting exhaustion phenotype that occurs with the industry-standard activation methods (25–30% PD-1+ with Akadeum method compared to >90% with traditional workflow). This method effectively activates T cells, with significant upregulation of standard activation markers, greater than 20-fold expansion, and desirable effector cell ratios. These cells are also highly transducible. Taken together, these data show that Akadeum’s microbubble-based workflow provides all of the critical aspects of CAR T cell generation while eliminating many of the most significant hurdles.
ISSN:0022-1767
1550-6606
DOI:10.4049/jimmunol.210.Supp.249.16