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Preclinical study of peripheral nerve regeneration using nerve guidance conduits based on polyhydroxyalkanaotes

Lorena R. Lizarraga‐Valderrama, Giulia Ronchi, Rinat Nigmatullin, Federica Fregnan, Pooja Basnett, Alexandra Paxinou, Stefano Geuna, Ipsita Roy

2021Bioengineering & Translational Medicine38 citationsDOIOpen Access PDF

Abstract

Nerve guidance conduits (NGCs) are used as an alternative to the "gold standard" nerve autografting, preventing the need for surgical intervention required to harvest autologous nerves. However, the regeneration outcomes achieved with the current NGCs are only comparable with autografting when the gap is short (less than 10 mm). In the present study, we have developed NGCs made from a blend of polyhydroxyalkanoates, a family of natural resorbable polymers. Hollow NGCs made from a 75:25 poly(3-hydroxyoctanoate)/poly(3-hydroxybutyrate) blend (PHA-NGCs) were manufactured using dip-molding. These PHA-NGCs showed appropriate flexibility for peripheral nerve regeneration. In vitro cell studies performed using RT4-D6P2T rat Schwann cell line confirmed that the material is capable of sustaining cell proliferation and adhesion. PHA-NGCs were then implanted in vivo to repair 10 mm gaps of the median nerve of female Wistar rats for 12 weeks. Functional evaluation of the regenerated nerve using the grasping test showed that PHA-NGCs displayed similar motor recovery as the autograft, starting from week 7. Additionally, nerve cross-sectional area, density and number of myelinated cells, as well as axon diameter, fiber diameter, myelin thickness and g-ratio obtained using the PHA-NGCs were found comparable to an autograft. This preclinical data confirmed that the PHA-NGCs are indeed highly promising candidates for peripheral nerve regeneration.

Topics & Concepts

Regeneration (biology)Nerve guidance conduitPeripheral nerveAxonBiomedical engineeringMaterials scienceIn vivoPolyhydroxyalkanoatesMedicineAnatomyBiologyCell biologyBiotechnologyGeneticsBacteriaNerve injury and regenerationGraphene and Nanomaterials ApplicationsElectrospun Nanofibers in Biomedical Applications