The study addressed the production of a hydrogel nanofiber skin cover and included the fabrication of hydrogel nanofibers from a blend of polyvinyl alcohol and alginate. The resulting fibrous layer was then crosslinked with glutaraldehyde, and, after 4 h of crosslinking, although the gelling component, i.e., the alginate, crosslinked, the polyvinyl alcohol failed to do so. The experiment included the comparison of the strength and ductility of the layers before and after crosslinking. It was determined that the fibrous layer following crosslinking evinced enhanced mechanical properties, which acted to facilitate the handling of the material during its application. The subsequent testing procedure proved that the fibrous layer was not cytotoxic. The study further led to the production of a modified hydrogel nanofiber layer that combined polyvinyl alcohol with alginate and albumin. The investigation of the fibrous layers produced determined that following contact with water the polyvinyl alcohol dissolved leading to the release of the albumin accompanied by the swelling of the alginate and the formation of a hydrogel.
This research involved
the production of polycaprolactone fiber
layers via the alternating current electrospinning method. To construct
the micro/nanofiber scaffold, mixtures of two molecular weight solutions,
M
n
45 000 and
M
n
80 000, were spun in differing proportions in a solvent system
containing acetic acid, formic acid, and acetone in a ratio of 1:1:1.
The composite fiber materials with hydroxyapatite particles were prepared
from a solution that combined the different molecular weight solutions
at a ratio of 1:3. The study resulted in the preparation of fiber
layers containing 0, 5, 10, and 15% (wt) hydroxyapatite particles
from the dry mass of the polycaprolactone. The strength, wettability,
and surface energy of the composite materials were examined, and the
results demonstrated that hydroxyapatite affects the fiber diameters,
strength, and surface energy and, thus, the wettability of the fiber
layers. The fibrous layers produced were further tested for cytotoxicity
and cell viability and proliferation. The results obtained thus strongly
indicate that the resulting bulky micro/nanofiber layers are suitable
for further testing with a view to their eventual application in the
field of bone tissue engineering.
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