A biomaterial platform for T cell-specific gene delivery

Efficient Capture and Traceless Release of Functional CD8+ T Cells with a Microfluidic Chip for Enhanced In Vitro and In Vivo CD4-CAR Transduction

The chimeric antigen receptor (CAR) T cells targeting CD4 expressed cells in acute lymphoblastic leukemia (T-ALL) and acute myeloid leukemia (AML) could reduce the risk of off target effects in normal tissues. However, the efficacy of adoptive cell therapy is predominantly attributed to CD8+ T cells, necessitating their purification before lentivirus transfection to enhance the production of CD4-CAR-T cells. In this study, we developed a microfluidic chip functionalized with an optimized CD8 aptamer, A3t-MU, to facilitate the enrichment and purification of CD8+ T cells. The presented chip showed efficient capture and seamless release of CD8+ T cells from cultured T cells and peripheral blood mononuclear cells (PBMCs). The purity of the released CD8+ T cells reached 98.1%, representing a 13% improvement over the conventional magnetic bead separation method. CD4-CAR was efficiently transduced into the purified CD8+ T cells to construct CAR-T cells. We evaluated the antitumor capability of the CD4-CAR transduced CD8+ T cells (anti-CD4 CD8-CAR T cells) both in vitro and in vivo. The anti-CD4 CD8-CAR T cells exhibited significant cancer-cell-killing capacity across multiple tumor cell lines, including CEM, Jurkat, and MV4-11. Meanwhile, anti-CD4 CD8-CAR T cells significantly inhibited tumor growth in vivo. In conclusion, the presented microfluidic chip offers a cost-effective and high-purity approach for CD8+ T cell separation, enhancing CD4-CAR transduction and achieving efficient antitumor capability both in vitro and in vivo.

Implantable CAR T cell factories enhance solid tumor treatment

Chimeric Antigen Receptor (CAR) T cell therapy has produced revolutionary success in hematological cancers such as leukemia and lymphoma. Nonetheless, its translation to solid tumors faces challenges due to manufacturing complexities, short-lived in vivo persistence, and transient therapeutic impact. We introduce 'Drydux' - an innovative macroporous biomaterial scaffold designed for rapid, efficient in-situ generation of tumor-specific CAR T cells. Drydux expedites CAR T cell preparation with a mere three-day turnaround from patient blood collection, presenting a cost-effective, streamlined alternative to conventional methodologies. Notably, Drydux-enabled CAR T cells provide prolonged in vivo release, functionality, and enhanced persistence exceeding 150 days, with cells transitioning to memory phenotypes. Unlike conventional CAR T cell therapy, which offered only temporary tumor control, equivalent Drydux cell doses induced lasting tumor remission in various animal tumor models, including systemic lymphoma, peritoneal ovarian cancer, metastatic lung cancer, and orthotopic pancreatic cancer. Drydux's approach holds promise in revolutionizing solid tumor CAR T cell therapy by delivering durable, rapid, and cost-effective treatments and broadening patient accessibility to this groundbreaking therapy.