A new bonding method enabling instant and effective adhesion of hydrogels has potential to broadly advance new biomaterials solutions for multiple unmet clinical needs
Highly adhesive and mechanically strong Dural Tough Adhesive addresses multiple limitations in the repair of the dural membrane lining the brain and spinal cord after trauma and surgeries
T cell development can be mechanically steered in vitro with engineered tissue-mimicking biomaterials, opening new ways to advance cell manufacturing in adoptive T cell therapies
Controlling inflammation enables injured aged muscle recovery via non-invasive mechanical loading, offering promise for the future of mechanotherapies for elderly patients.
Integrated biomaterials approach that enhances adoptively transferred T cell therapy with cancer vaccine technology provides strong and long-lasting effects against solid tumors
Fine-tuning stimulation doses to deficiencies in patient-specific CAR-T cells, using artificial antigen-presenting scaffolds, enables manufacturing of more potent CAR-T cell products.
