ABSTRACT The long-term goal of this project is to develop and validate an injectable, biodegradable nanowire delivery platform for local and sustained release of a “painless” nerve growth factor (NGF) isoform to accelerate fracture healing in clinical scenarios of delayed healing. Approximately 15 million fracture injuries occur each year in the United States (US).6 An estimated 10-15% of fractures within a healthy population result in delayed- or non-union.7,8 However, delayed healing rates increase to almost 50% in patients with vascular damage or high co-morbidity burdens such as diabetes, increased age, smoking, and obesity.9,10 The current standard of care for delayed healing or non-union is surgical intervention to increase stability or to promote healing through application of bone grafts. Bone morphogenetic protein (BMP) is the only biologic with FDA approval for use in fracture repair, with “on-label” use only within a narrow indication window. However, BMP requires surgical implantation and is typically limited to only the most at-risk fractures due to the high cost, limited evidence of clinical efficacy, and risk of severe off-target effects.11-14 As such, there exists an unmet clinical need for biologics that could stimulate bone regeneration in a non-surgical delivery platform. This application builds on strong preliminary data demonstrating that NGF accelerates fracture repair when injected into the cartilaginous phase of long bone healing. Importantly, our preliminary data is the first to show that NGF acts on chondrocytes to promote programs associated with endochondral ossification (EO). The goal of this grant is to build upon these preliminary data to develop NGF into a platform suitable for clinical translation. In the first Aim, we optimize the dose and timing of a mutant form of NGF (NGFR100W) to stimulate endochondral fracture repair. NGFR100W is a novel “painless” NGF that efficiently binds to the TrkA receptor to provide the same trophic effect as wild type NGF, but fails to bind to the p75NTR receptor to significantly reduce risk of nociception.15,16 In the second Aim, we probe the mechanism by which NGF/NGFR100W stimulates fracture repair by conditionally deleting the TrkA receptor. To date the molecular pathways stimulated by therapeutic delivery of NGF have not been rigorously studied in long bone fracture healing. Lastly, in the third Aim, we modify our previously developed injectable heparin coated polycaprolactone (PCL) nanowires17 for encapsulation and sustained delivery of painless NGF. Here we also incorporate a pre-clinical model of diabetes (Lepob) established to demonstrate delayed healing to challenge our therapy in a clinically relevant scenario of malunion. These aims allow us to test the central hypothesis that a painless NGF therapy can improve fracture healing by acting through TrkA signaling to stimulate chondrocyte-to-osteoblast transformation. Our interdisciplinary team of experts in fracture healing,...