posted on 2022-06-03, 10:43authored byMcKay Cavanaugh, Darya Asheghali, Cecilia M. Motta, Elena Silantyeva, Shantanu P. Nikam, Matthew L. Becker, Rebecca K. Willits
Peripheral
nerve regeneration across large gaps remains clinically
challenging and scaffold design plays a key role in nerve tissue engineering.
One strategy to encourage regeneration has utilized nanofibers or
conduits to exploit contact guidance within the neural regenerative
milieu. Herein, we report the effect of nanofiber topography on two
key aspects of regeneration: Schwann cell migration and neurite extension.
Substrates possessing distinct diameter distributions (300 ±
40 to 900 ± 70 nm) of highly aligned poly(ε-caprolactone)
nanofibers were fabricated by touch-spinning. Cell migratory behavior
and contact guidance were then evaluated both at the tissue level
using dorsal root ganglion tissue explants and the cellular level
using dissociated Schwann cells. Explant studies showed that Schwann
cells emigrated significantly farther on fibers than control. However,
both Schwann cells and neurites emigrated from the tissue explants
directionally along the fibers regardless of their diameter, and the
data were characterized by high variation. At the cellular level,
dissociated Schwann cells demonstrated biased migration in the direction
of fiber alignment and exhibited a significantly higher biased velocity
(0.2790 ± 0.0959 μm·min–1) on 900
± 70 nm fibers compared to other nanofiber groups and similar
to the velocity found during explant emigration on 900 nm fibers.
Therefore, aligned, nanofibrous scaffolds of larger diameters (900
± 70 nm) may be promising materials to enhance various aspects
of nerve regeneration via contact guidance alone. While cells track
along with the fibers, this contact guidance is bidirectional along
the fiber, moving in the plane of alignment. Therefore, the next critical
step to direct regeneration is to uncover haptotactic cues that enhance
directed migration.