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Technologies 24
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Nixe: Bioinspired Sustainable and Water-repellent Textile Coating Next-generation PFAS-free water-repellent textile coating solution with utility for multiple industries and potential to dramatically reduce the use of “forever chemicals.” -
Injectable Hydrogel Adhesive for Improved Muscle Regeneration A super-strong, stretchy, and self-healing biomaterial that adheres to muscles and helps them heal faster after injury. -
Metabolically Labeled CAR-T Cells Against Cancer Through a simple and effective metabolic labeling approach, patient-derived T cells engineered to carry immune-enhancing cytokines on their surfaces could help expand adoptive T cell therapies to treatment of solid tumors and improve blood cancer therapies. -
ReConstruct: Vascularized Tissue for Breast Reconstruction and Augmentation ReConstruct is a platform for growing, vascularizing, and implanting patient-derived tissues that enable safer breast reconstruction after cancer surgery. -
Cellular “Backpacks” to Fight Cancer, Autoimmune Disorders, and More Macrophages are very malleable immune cells, but that also means that they can be influenced by cancerous tumors and inflammatory processes. Our cellular "backpacks" stick to macrophages and can deliver molecules that keep them in their desired state for cell therapy and more. -
Tunable ECMs for More Effective T cell Therapies Tunable hydrogels that enhance the efficacies of adoptively transferred immune cells during their manufacturing by mimicking target tissue biomechanics.
i3 Center: Biomaterials to Create T Cell Immunity Cancer immunologists and biological engineers are developing new biomaterials-based approaches to develop new anti-cancer immunotherapies for treatment-resistant cancers. 
Add to CalendariCalendarGoogle CalendarOutlook From Mechanical Forces to Tissue Straining – How Biophysical Cues Can Be Used to Guide Regeneration: Topics in Bioengineering Seminar Harvard John A. Paulson School of Engineering and Applied Sciences Topics in Bioengineering presents this lecture by Georg Duda, Wyss Institute Associate Faculty Member. Conceptually, our research aims at understanding endogenous cascades of tissue formation, cytokine signaling and cellular self-organization especially in bone. Mechanical straining and adaptation due to mechanical cues plays a central role... Free and open to public