In
this study, silk filaments are coated with different concentrations
(5, 7.5, and 10% w/w) of carbon nanofibers (CNFs) dispersed in poly-ε-caprolactone.
The nanocomposite-coated silk filaments are subjected to knitting,
braiding, and twisting. The tubular structures are covered with a
silk fibroin/polyvinyl film for the nerve conduit application. Physical
characterization of the developed nerve conduits demonstrates suitable
mechanical properties comparable to native nerve tissue. Cell proliferation
is confirmed through in vitro cell culture studies using Neuro 2a
and rat primary cortical neural progenitor cells, which show that
the proliferation happens along the interconnected macrochannels of
the internal structure of the nerve conduit. The knitted structure
presents better biological properties than the nerve conduits with
other internal structures. The in vivo sciatic nerve implantation
is performed in a rabbit model using the best conduit, i.e., 10% CNF-based
nanocomposite-coated silk with a knitted inner structure without any
biomolecules or tube filling gels. Regeneration of a 2 cm gap excised
sciatic nerve is investigated by immunohistochemistry and histology
of implanted nerve conduits removed after 30 days. Results suggest
that the CNF-based conducting nanocomposite coating in this well-defined
architecture of the conduit helps in signal transmission and neural
growth during the regeneration of the transected nerve.
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