Access to clean water
is a global challenge, and fog collectors
are a promising solution. Polycarbonate (PC) fibers have been used
in fog collectors but with limited efficiency. In this study, we show
that controlling voltage polarity and humidity during the electrospinning
of PC fibers improves their surface properties for water collection
capability. We experimentally measured the effect of both the surface
morphology and the chemistry of PC fiber on their surface potential
and mechanical properties in relation to the water collection efficiency
from fog. PC fibers produced at high humidity and with negative voltage
polarity show a superior water collection rate combined with the highest
tensile strength. We proved that electric potential on surface and
morphology are crucial, as often designed by nature, for enhancing
the water collection capabilities via the single-step
production of fibers without any postprocessing needs.
Atopic
dermatitis (eczema) is a widespread disorder, with researchers
constantly looking for more efficacious treatments. Natural oils are
reported to be an effective therapy for dry skin, and medical textiles
can be used as an alternative or supporting therapy. In this study,
fibrous membranes from poly(vinyl butyral-co-vinyl alcohol-co-vinyl
acetate) (PVB) with low and high molecular weights were manufactured
to obtain nano- and micrometer fibers
via
electrospinning
for the designed patches used as oil carriers for atopic skin treatment.
The biocompatibility of PVB patches was analyzed using proliferation
tests and scanning electron microscopy (SEM), which combined with
a focused ion beam (FIB) allowed for the 3D visualization of patches.
The oil spreading tests with evening primrose, black cumin seed, and
borage were verified with cryo-SEM, which showed the advantage nanofibers
have over microfibers as carriers for low-viscosity oils. The skin
tests expressed the usability and the enhanced oil delivery performance
for electrospun patches. We demonstrate that through the material
nano- and microstructure, commercially available polymers such as
PVB have great potential to be deployed as a biomaterial in medical
applications, such as topical treatments for chronic skin conditions.
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