TY - GEN AB - The bone tissue is a complex nanocomposite, organized in a calcified extracellular matrix. Bone autografts remain the gold standard to treat traumatic bone injuries. However, autografts can increase morbidity of the patient?s donor site and has limited availability. On the other hand, bioprinted microgels are attractive biomaterials that offer injectability, tunability, and acts as a cargo to deliver therapeutic proteins and cells. Here, we aim to bioprint and mineralize cell-laden gelatin methacrylate (GelMA) microgels and test the effects of cryopreservation on cell viability for bone tissue engineering applications. AD - Oregon Health and Science University AD - Oregon Health and Science University AD - Oregon Health and Science University AD - Oregon Health and Science University AD - Oregon Health and Science University AU - Sousa, Mauricio AU - Balbinot, Gabriela AU - Visalakshan, Rauhl AU - Subiah, Ramesh AU - Bertassoni, Luiz DA - 2022 DO - 10.6083/8623hz558 DO - DOI ID - 9584 KW - Bioprinting KW - Bone Regeneration KW - Microgels KW - Osteocytes KW - mineralization KW - bone grafting KW - autograft L1 - https://digitalcollections.ohsu.edu/record/9584/files/Sousa-Mauricio-OHSU-ResearchWeek-2022.pdf L2 - https://digitalcollections.ohsu.edu/record/9584/files/Sousa-Mauricio-OHSU-ResearchWeek-2022.pdf L4 - https://digitalcollections.ohsu.edu/record/9584/files/Sousa-Mauricio-OHSU-ResearchWeek-2022.pdf LA - eng LK - https://digitalcollections.ohsu.edu/record/9584/files/Sousa-Mauricio-OHSU-ResearchWeek-2022.pdf N2 - The bone tissue is a complex nanocomposite, organized in a calcified extracellular matrix. Bone autografts remain the gold standard to treat traumatic bone injuries. However, autografts can increase morbidity of the patient?s donor site and has limited availability. On the other hand, bioprinted microgels are attractive biomaterials that offer injectability, tunability, and acts as a cargo to deliver therapeutic proteins and cells. Here, we aim to bioprint and mineralize cell-laden gelatin methacrylate (GelMA) microgels and test the effects of cryopreservation on cell viability for bone tissue engineering applications. PB - Oregon Health and Science University PY - 2022 T1 - Biomimetic nanoscale mineralization of bioprinted cell- laden microgels TI - Biomimetic nanoscale mineralization of bioprinted cell- laden microgels UR - https://digitalcollections.ohsu.edu/record/9584/files/Sousa-Mauricio-OHSU-ResearchWeek-2022.pdf Y1 - 2022 ER -