UC Irvine

Autologous cell therapy depends on T lymphocyte expansion efficiency and is hindered by suboptimal interactions between T cell receptors (TCR) and peptide-MHC molecules. Various artificial antigen presenting cell systems that enhance these interactions are often labor-intensive, fabrication costly, highly variable, and potentially unscalable toward clinical setting. Here, 3D centrifugation-enabled priming of T cell immune-synapse junctions is performed to generate tight T cell–Dynabead aggregates at a rate 200-fold faster than that of conventional 24-h bulk shaking. Furthermore, by forming T cell–Dynabead aggregates in the starting culture, two- to sixfold greater T cell expansion is achieved over conventional T cell expansion for cancer patient-derived primary T cells while limiting over-activation. Creating 3D T cell–Dynabead aggregates as the “booster” material enables highly efficient polyclonal T cell expansion without the need for complex surface modification of artificial antigen-presenting cells (APCs). This method can be modularly adapted to existing T cell expansion processes for various applications, including adoptive cell therapies (ACTs).