Particle elasticity influences polymeric artificial antigen presenting cell effectiveness in vivo via CD8+ T cell activation, macrophage uptake, and the protein corona

Adoptive cell therapy (ACT) is an immunotherapy strategy for cancer that has seen widespread clinical success. During ACT, patient-derived lymphocytes are stimulated with the antigen of interest ex vivo , proliferated, then returned to the patient to initiate an antigen-specific antitumor response. While effective, this process is resource-intensive and logistically impossible for many patients. Particulate artificial antigen presenting cells (aAPCs) offer a potential “off-the-shelf” alternative to ex vivo ACT. While particulate aAPCs perform well in vitro , they have had limited success in vivo due to poor bioavailability after injection. Barriers to bioavailability include rapid clearance, unfavorable biodistribution, and inadequate interactions with CD8+ T cells at sites of interest. Biomaterial properties such as elasticity have been shown to vastly impact the bioavailability and particle-cell interactions, but this has yet to be investigated in the context of aAPCs for in vivo T-cell stimulation. Previous literature likewise indicates that biomaterial properties, especially elasticity, can modulate T-cell activation in vitro . With the goal of creating a more biomimetic, next-generation particulate aAPC, we developed a poly(ethylene) glycol hydrogel particle platform with tunable elasticity to investigate the impact of elasticity on antigen-specific T cell activation for in vivo adoptive transfer. Using this knowledge, we were able to gain more precise control over in vivo T cell activation and investigate possible mechanisms including the effects of aAPC elasticity on T cell binding, macrophage uptake, and the protein corona.