These studies suggest that this bioactive glass possesses a robust proangiogenic potential, and this strategy may provide an alternative to recombinant inductive growth factors.
Localized radiation is an effective treatment modality for carcinomas, yet the associated reduction of the host vasculature significantly inhibits the tissue's regenerative capacity. Low concentrations of bioactive glass (BG) possess angiogenic potential, and we hypothesized that localized BG presentation would increase neovascularization and promote healing in an irradiated bone defect. An isolated calvarial region of Sprague-Dawley rats was irradiated 2 weeks before surgery. Bilateral critical-sized defects were created and immediately filled with a BG-loaded collagen sponge or an empty sponge as an internal control. Histological analysis of calvaria collected after 2 weeks demonstrated greater neovascularization within the defect in the presence of BG than with collagen alone. Noninvasive ultrasound imaging at 4 weeks detected less contrast agent in the brain below BG-treated defects than in the nearby untreated defects and images of treated defects acquired at 2 weeks. The reduced ability to detect contrast agent in BG-treated defects suggested greater attenuation of ultrasound signal due to early bone formation. Micro-computed tomography imaging at 12 weeks demonstrated significantly greater bone volume fraction within BG-treated defects than in controls. These results suggest that neovascularization induced by localized BG delivery promotes bone regeneration in this highly compromised model of bone healing and may offer an alternative approach to costly growth factors and their potential side-effects.
Neuroma management is an unresolved problem. Biomaterials to limit unwanted axonal growth could be a tool to manage neuroma. Hyaluronic acid/carboxymethyl cellulose (HA/CMC) is an antiadhesive, biodegradable material that is nontoxic to nerve. The purpose of this study was to evaluate the efficacy of this biomaterial to limit axonal growth. Rats received a sciatic nerve transection and repair with a short conduit (5 mm) containing HA/CMC, fibrin, or nothing (empty conduit). In another study, nerve was transected and either left undisturbed or wrapped with HA/CMC around the proximal and distal ends. In a final study, nerve was transected and repaired with an HA/CMC wrap. Four weeks following the procedures, nerves were harvested and assessed using histomorphometry to measure axonal regeneration. Axonal regeneration following transection was significantly inhibited by direct axonal contact with HA/CMC, whether within a conduit or wrapped around the transected proximal nerve end. Axonal regeneration following epineurial repair was not affected by HA/CMC wrapped around nerve, demonstrating axonal growth inhibition due to direct contact of regenerating axons with HA/CMC. These studies demonstrate the efficacy of HA/CMC to limit axonal outgrowth by contact with regenerating axons. HA/CMC barriers may prove to be a tool to prevent neuroma formation by inhibiting axonal growth. © 2015 Wiley Periodicals, Inc. J Biomed Mater Res Part B: Appl Biomater, 105B: 568-574, 2017.
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