Short and long gap peripheral nerve repair with magnesium metal filaments.

A current clinical challenge is to replace autografts for repair of injury gaps in peripheral nerves, which can occur due to trauma or surgical interruption. Biodegradable metallic magnesium filaments, placed inside hollow nerve conduits, could support nerve repair by providing contact guidance support for axonal regeneration. This was tested by repairing sciatic nerves of adult rats with single magnesium filaments placed inside poly(caprolactone) nerve conduits. Controls were empty conduits, conduits containing titanium filaments and/or isografts from donor rats. With a nerve gap of 6 mm and 6 weeks post-repair, magnesium filaments had partially resorbed. Regenerating cells had attached to the filaments and axons were observed in distal stumps in all animals. Axon parameters were improved with magnesium compared to conduits alone or conduits with single titanium filaments. With a longer gap of 15 mm and 16 weeks post-repair, functional parameters were improved with isografts, but not with magnesium filaments or empty conduits. Magnesium filaments were completely resorbed and no evidence of scarring was seen. While axon outgrowth was not improved with the longer gap, histological measures of the tissues were improved with magnesium compared to empty conduits. Therefore, the use of magnesium filaments is promising because they are biocompatible and improve aspects of nerve regeneration. © 2017 Wiley Periodicals, Inc. J Biomed Mater Res Part A: 105A: 3148-3158, 2017.

Ethylene Oxide Sterilization Preserves Bioactivity and Attenuates Burst Release of Encapsulated Glial Cell Line Derived Neurotrophic Factor from Tissue Engineered Nerve Guides For Long Gap Peripheral Nerve Repair.

Synthetic nerve guides are widely utilized to reconstruct peripheral nerve defects that are less than three centimeters. However, there are no clinically available nerve guides that are approved to promote repair over long gaps (>3 cm). Many currently available guides are unable to sustain large defect regeneration either because of limitations in fabrication or short degradation times in vivo. Furthermore, current clinically available nerve guides do not contain neurotrophic factor delivery systems to promote nerve tissue regeneration over long gaps. The purpose of this paper is to describe the manufacturing parameters and sterilization procedures of a 5.2 cm poly(caprolactone) nerve conduit with embedded polymeric microspheres that encapsulate glial cell line-derived neurotrophic factor (GDNF) for implantation into a preclinical rhesus macaque 5 cm median nerve defect model. Nerve conduits were sterilized with room temperature ethylene oxide (RT EtO) and assessed for morphology as well as maintenance of porosity. Release kinetics and bioactivity of GDNF were also assessed in RT EtO sterilized guides. Scanning electron microscopy indicated that RT EtO treatment did not affect morphology and porosity percentage of nerve guides. Furthermore, RT EtO had no effect on GDNF bioactivity based on Schwannoma cell migration studies. RT EtO guides exhibited significantly slowed GDNF release compared to GDNF release from nonsterile guides indicating that EtO treatment may enhance the long-term delivery kinetics of GDNF from polymeric microspheres within the nerve guide.

Initial observations on using magnesium metal in peripheral nerve repair.

Biodegradable magnesium metal filaments placed inside biodegradable nerve conduits might provide the physical guidance support needed to improve the rate and extent of regeneration of peripheral nerves across injury gaps. In this study, we examined basic issues of magnesium metal resorption and biocompatibility by repairing sub-critical size gap injuries (6 mm) in one sciatic nerve of 24 adult male Lewis rats. Separated nerve stumps were connected with poly(caprolactone) nerve conduits, with and without magnesium filaments (0.25 mm diameter, 10 mm length), with two different conduit filler substances (saline and keratin hydrogel). At 6 weeks after implantation, magnesium degradation was examined by micro-computed tomography and histological analyses. Magnesium degradation was significantly greater when the conduits were filled with an acidic keratin hydrogel than with saline (p < 0.05). But magnesium filaments in some animals remained intact for 6 weeks. Using histological and immunocytochemical analyses, good biocompatibility of the magnesium implants was observed at 6 weeks, as shown by good development of regenerating nerve mini-fascicles and only mild inflammation in tissues even after complete degradation of the magnesium. Nerve regeneration was not interrupted by complete magnesium degradation. An initial functional evaluation, determination of size recovery of the gastrocnemius muscle, showed a slight improvement due to magnesium with the saline but not the keratin filler, compared with respective control conduits without magnesium. These results suggest that magnesium filament implants have the potential to improve repair of injured peripheral nerve defects in this rodent model.