Efficient and Traceless Aptamer-Based Serial Selection of Naïve and Early Memory CD8 T Cells for CAR T Cell Therapy.

Chimeric antigen receptor (CAR) T cell therapies have shown clinical success in cancer treatment. However, the compositions of the final products can differ substantially between patients, leading to variable treatment responses. Recent studies suggest that CAR T cells manufactured from defined T cell subsets show greater potency and persistence and improved predictability of therapeutic efficacy.

DNA Aptamer-Polymer Conjugates for Selective Targeting of Integrin α4β1 T-Lineage Cancers.

Selective therapeutic targeting of T-cell malignancies is difficult due to the shared lineage between healthy and malignant T cells. Current front-line chemotherapy for these cancers is largely nonspecific, resulting in frequent cases of relapsed/refractory disease. The development of targeting approaches for effectively treating T-cell leukemia and lymphoma thus remains a critical goal for the oncology field.

Aptamer-Based Traceless Multiplexed Cell Isolation Systems.

In both biomedical research and clinical cell therapy manufacturing, there is a need for cell isolation systems that recover purified cells in the absence of any selection agent. Reported traceless cell isolation methods using engineered antigen-binding fragments or aptamers have been limited to processing a single cell type at a time. There remains an unmet need for cell isolation processes that rapidly sort multiple target cell types.

Discovery of a Transferrin Receptor 1-Binding Aptamer and Its Application in Cancer Cell Depletion for Adoptive T-Cell Therapy Manufacturing.

The clinical manufacturing of chimeric antigen receptor (CAR) T cells includes cell selection, activation, gene transduction, and expansion. While the method of T-cell selection varies across companies, current methods do not actively eliminate the cancer cells in the patient's apheresis product from the healthy immune cells. Alarmingly, it has been found that transduction of a single leukemic B cell with the CAR gene can confer resistance to CAR T-cell therapy and lead to treatment failure.

Biomaterials in Chimeric Antigen Receptor T-Cell Process Development.

Chimeric antigen receptor (CAR) T-cell therapy has transformed the cancer treatment landscape, utilizing modified autologous T cells to treat relapsed or refractory B-cell leukemias and lymphomas. However, the therapy's broader impact has been limited, in part, by a complicated, lengthy, and expensive production process. Accordingly, as CAR T-cell therapies are further advanced to treat other cancers, continual innovation in cell manufacturing will be critical to their successful clinical implementation.

Traceless aptamer-mediated isolation of CD8 T cells for chimeric antigen receptor T-cell therapy.

Chimeric antigen receptor T-cell therapies using defined product compositions require high-purity T-cell isolation systems that, unlike immunomagnetic positive enrichment, are inexpensive and leave no trace on the final cell product. Here, we show that DNA aptamers (generated with a modified cell-SELEX procedure to display low-nanomolar affinity for the T-cell marker CD8) enable the traceless isolation of pure CD8 T cells at low cost and high yield. Captured CD8 T cells are released label-free by complementary oligonucleotides that undergo toehold-mediated strand displacement with the aptamer.