Wound Repair and Regeneration,
Journal Year:
2024,
Volume and Issue:
33(1)
Published: Nov. 14, 2024
Abstract
Traditional
wound
dressings,
despite
their
widespread
use,
face
limitations,
such
as
poor
infection
control
and
insufficient
healing
promotion.
To
address
these
challenges,
bioactive
materials
have
emerged
a
promising
solution
in
care.
This
comprehensive
review
explores
the
latest
developments
technologies,
starting
with
an
overview
of
importance
effective
management,
emphasising
need
for
advanced
dressings.
The
further
various
materials,
defining
characteristics.
It
covers
wide
range
natural
synthetic
biopolymers
used
to
develop
Next,
paper
discusses
incorporation
agents
into
including
antimicrobial
anti‐inflammatory
agents,
alongside
regenerative
components
like
growth
factors,
platelet‐rich
plasma,
fibrin
stem
cells.
also
fabrication
techniques
highlighting
electrospinning,
which
facilitated
production
nanofibre‐based
dressings
controlled
porosity,
sol–gel
method
developing
glass‐based
3D
bioprinting
customised,
patient‐specific
concludes
by
addressing
challenges
future
perspectives
dressing
development.
includes
regulatory
considerations,
clinical
efficacy,
patient
care
protocol
integration
progress
monitoring.
Furthermore,
considers
emerging
trends
smart
sensors
personalised
medicine
approaches,
offering
insights
direction
research.
Molecules,
Journal Year:
2024,
Volume and Issue:
29(17), P. 4271 - 4271
Published: Sept. 9, 2024
In
recent
years,
a
wide
variety
of
high-performance
and
versatile
nanofiber
membranes
have
been
successfully
created
using
different
electrospinning
methods.
As
vehicles
for
medication,
they
receiving
more
attention
because
their
exceptional
antibacterial
characteristics
ability
to
heal
wounds,
resulting
in
improved
drug
delivery
release.
This
quality
makes
them
an
appealing
choice
treating
various
skin
conditions
like
fungal
infections,
discoloration
disorders,
dermatitis,
cancer.
article
offers
comprehensive
information
on
the
procedure,
categorization
membranes,
use
dermatology.
Additionally,
it
delves
into
successful
case
studies,
showcasing
utilization
field
diseases
promote
substantial
advancement.
International Journal of Nanomedicine,
Journal Year:
2024,
Volume and Issue:
Volume 19, P. 13973 - 13990
Published: Dec. 1, 2024
Globally,
wound
care
has
become
a
significant
burden
on
public
health,
with
annual
medical
costs
reaching
billions
of
dollars,
particularly
for
the
long-term
treatment
chronic
wounds.
Traditional
treatments,
such
as
gauze
and
bandages,
often
fail
to
provide
an
ideal
healing
environment
due
their
lack
effective
biological
activity.
Consequently,
researchers
have
increasingly
focused
developing
new
dressings.
Among
these,
electrospinning
technology
garnered
considerable
attention
its
ability
produce
nano-scale
fine
fibers.
This
type
dressing,
unique
physical
chemical
properties-especially
in
enhancing
breathability,
increasing
specific
surface
area,
optimising
porosity,
improving
flexibility-demonstrates
advantages
promoting
healing,
reducing
risk
infection,
overall
outcomes.
Additionally,
application
natural
products
from
plants
further
enhances
effectiveness
These
not
only
exhibit
good
biocompatibility
but
are
also
rich
pharmacologically
active
ingredients,
antibacterial,
anti-inflammatory,
antioxidant
compounds.
They
can
serve
both
substrate
nanofibers
bioactive
components,
effectively
cell
proliferation
tissue
regeneration,
thereby
accelerating
complications.
article
reviews
plant
product
prepared
by
focussing
development
optimisation
these
nanofibers,
discussing
challenges
using
this
technology,
outlining
future
research
directions
prospects
field.
ACS Applied Nano Materials,
Journal Year:
2024,
Volume and Issue:
7(16), P. 19407 - 19415
Published: Aug. 14, 2024
Large-scale
spinning
of
high-performance
SiO2
porous
nanofibers
remains
a
pivotal
challenge
in
facilitating
their
utilization
for
flexible
thermal
insulation
purposes.
Herein,
massive
was
achieved
through
the
solution
blow
(SBS)
process
utilizing
microemulsion
polysiloxane
solutions.
Using
MK
siloxane
polymer
as
Si
source,
characterized
by
high
purity
and
excellent
uniformity
obtained.
Multicomponent
spinnable
precursor
prepared
incorporating
paraffin
sacrificial
phase,
Span
80
Tween
surfactants,
polyvinylpyrrolidone
aid.
Through
optimization
composition
SBS
parameters,
high-speed
paraffin/MK
accomplished
with
rate
20
mL·h–1.
Subsequent
high-temperature
pyrolysis
facilitated
conversion
organic
into
controllable
pores
structure.
Porous
nanofiber
sponges
fabricated
using
technique
exhibit
distinctive
lightweight
properties
[0.037
W·(m·K)−1].
These
promise
to
facilitate
inorganic
fiber
applications
management.
