PROJECT SUMMARY This proposal presents a five-year research career development program focused on optimizing the physical and biological characteristics of phosphorylated poly(ester ureas) (pPEU) for the stabilization and healing of rib fractures. The candidate is currently an Assistant Professor of Surgery and acute and critical care trauma surgeon at Duke University, with previous research experience in biologic materials and tissue engineering research. He has now chosen to focus on materials science and mechanical engineering with a diverse mentoring committee of investigators with expertise in materials, polymers, musculoskeletal reparative processes and stem cell research. The proposed experiments and didactic work will provide the candidate with a unique set of skills that will help him transition to independence as a surgeon-scientist and enable him to fill a significant “experience gap” in the field of research dedicated to rib fractures and wound healing. Rib fractures account for nearly 40% of all bone fractures sustained in the each year, with over a quarter million rib injuries. These injuries can have long-lasting effects, sometimes even for life. Over half of rib fracture patients contract pneumonia, and nearly two thirds will still experience significant pain in the chest wall years after sustaining the injury. While stabilization of a fracture promotes faster healing and decreased rates of non-union (failure of a broken bone to heal), rib fractures present a unique challenge in that immobilization can only be accomplished through invasive surgical intervention. Therefore, unlike long bone fractures where immediate stabilization is standard, this is reserved in rib fractures for only the most severe cases. Poly(ester ureas) (PEU) are amino acid based biodegradable polymers with bone like mechanical properties. One such phosphorylated PEU (pPEU) copolymer, based on phosphoserine (pSer) is ethanol soluble allowing for injection, with strong bone adhesion and high elastic moduli, making pPEU’s ideal as an innovative, non-invasive solution for the stabilization of rib fractures. However, the effect of pSer stoichiometry on PEU copolymer osteoinduction remains unknown, as well as if a provisional elastomeric callus using resorbable PEU based adhesive can accelerate bone healing through early fracture stabilization. This proposal will determine the relationships between the physical and biologic characteristics of injectable pSer-PEU for osteoinduction and test the safety and performance of pSer-PEU in a rat model of rib fracture. The work of this proposal will 1) characterize the relationship of pSer stoichiometry within the PEU copolymers on biomechanics (tensile strength, elastic modulus, and stiffness), and interfascial adhesion of pSer-PEU; 2) quantify bone marrow stromal cell (BMSC) cytoskeletal reorganization and osteoinduction to increased stiffness, and 3) evaluate fracture stability and callus formation in a rat rib fracture m...