| Literature DB >> 28156059 |
Martina Giannaccini1, M Pilar Calatayud2, Andrea Poggetti3, Silvia Corbianco3, Michela Novelli3, Melania Paoli4, Pietro Battistini3, Maura Castagna3, Luciana Dente1, Paolo Parchi3, Michele Lisanti3, Gabriella Cavallini3, Concepción Junquera5, Gerardo F Goya2, Vittoria Raffa1,4.
Abstract
The only clinically approved alternative to autografts for treating large peripheral nerve injuries is the use of synthetic nerve guidance conduits (NGCs), which provide physical guidance to the regenerating stump and limit scar tissue infiltration at the injury site. Several lines of evidence suggest that a potential future strategy is to combine NGCs with cellular or molecular therapies to deliver growth factors that sustain the regeneration process. However, growth factors are expensive and have a very short half-life; thus, the combination approach has not been successful. In the present paper, we proposed the immobilization of growth factors (GFs) on magnetic nanoparticles (MNPs) for the time- and space-controlled release of GFs inside the NGC. We tested the particles in a rat model of a peripheral nerve lesion. Our results revealed that the injection of a cocktail of MNPs functionalized with nerve growth factor (NGF) and with vascular endothelial growth factor (VEGF) strongly accelerate the regeneration process and the recovery of motor function compared to that obtained using the free factors. Additionally, we found that injecting MNPs in the NGC is safe and does not impair the regeneration process, and the MNPs remain in the conduit for weeks.Entities:
Keywords: delivery of growth factors; functional recovery; nanoparticle; nerve injury; nerve regeneration
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Year: 2017 PMID: 28156059 DOI: 10.1002/adhm.201601429
Source DB: PubMed Journal: Adv Healthc Mater ISSN: 2192-2640 Impact factor: 9.933