With
the
rapid
development
of
mobile
communication
technology
and
wearable
electronic
devices,
electromagnetic
radiation
generated
by
high-frequency
information
exchange
inevitably
threatens
human
health,
so
high-performance
interference
(EMI)
shielding
materials
are
urgently
needed.
The
2D
nanomaterial
MXene
exhibits
superior
EMI
performance
owing
to
its
high
conductivity,
however,
mechanical
properties
limited
due
porosity
between
nanosheets.
In
recent
years,
it
has
been
reported
that
introducing
natural
nanocellulose
as
an
organic
framework,
MXene/nanocellulose
composites
can
be
synergically
improved,
which
expected
widely
used
in
multifunctional
devices.
this
review,
wave
(EMW)
attenuation
mechanism
is
briefly
introduced,
latest
progress
applications
comprehensively
reviewed,
wherein
advantages
disadvantages
different
preparation
methods
various
types
summarized.
Finally,
challenges
perspectives
discussed,
regarding
improvement,
control
mechanism,
large-scale
production
composites.
This
review
provide
guidance
on
design
flexible
for
protection
future
intelligent
field.
Tissue
engineering
and
regenerative
medicine
are
multidisciplinary
disciplines
that
use
technical
biological
principles
to
create
workable
replacements
for
human
tissues
organ
function.
Keratin,
a
protein
found
in
materials
like
wool,
feathers,
hooves,
holds
great
promise
biomedical
applications
due
its
unique
properties.
It
is
biocompatible,
providing
suitable
matrix
cell
growth
tissue
repair.
Keratin's
cysteine-rich
composition
facilitates
attachment
growth,
supporting
the
regeneration
of
damaged
tissue.
The
method
electrospinning
flexible
effective
way
producing
nanofibers.
To
generate
fibers
with
high
surface
area
volume
ratio,
this
technique
applies
an
electric
field
draw
charged
threads
polymer
melts
or
solutions.
Further,
extraction,
purification,
characterization
keratin
proteins
from
hair
wool
have
yielded
significant
advances
over
past
century,
resulting
development
keratin-based
biomaterials
platforms.
Researchers
successfully
fabricated
nanofiber
scaffolds
using
techniques,
mimicking
natural
extracellular
(ECM)
promoting
infiltration
adhesion.
These
been
investigated
different
engineering,
vitro
studies
showing
successful
skin
cells
on
them,
making
them
promising
wound
healing
Keratin
biomaterial
utilized
because
biocompatibility,
biodegradability,
latent
activity,
cellular
binding
designs.
Understanding
scaffolds'
biodegradation,
stability
vivo,
mechanism
action
essential
more
sophisticated
applications,
including
clinical
research.
Additional
research
development,
addition
advancements
related
technologies,
ought
even
prospects
versatile
fascinating
biomaterial.
RSC Advances,
Год журнала:
2024,
Номер
14(47), С. 34756 - 34768
Опубликована: Янв. 1, 2024
Composite
electrospun
membranes
composed
of
quaternized
chitosan,
poly(ethylene
oxide)
and
either
caffeic
acid
or
berberine
demonstrated
improved
hydrophilicity
enhanced
antibacterial
activity
against
E.
coli
S.
aureus
.
Royal Society of Chemistry eBooks,
Год журнала:
2024,
Номер
unknown, С. 214 - 250
Опубликована: Ноя. 15, 2024
The
development
of
biocompatible
nanofibres
through
electrospinning
is
a
promising
method
for
engineers
in
the
biomedical
field.
existing
coating
technologies
medical
field
have
various
limitations,
and
more
investigations
are
needed
to
improve
their
biocompatibility,
controlled
release
properties,
mechanical
strength.
Designing
new
materials
that
can
interact
efficiently
with
biological
systems
offer
numerous
functional
advantages
major
challenge
device
manufacturing
tissue
engineering.
This
chapter
reviews
approaches
used
create
nanofibres,
including
design,
fabrication
functionalization.
applications
these
coatings
also
reviewed.
Furthermore,
we
discuss
methods,
used,
key
parameters
impact
fibre
morphology
physiochemical
properties.
Moreover,
incorporation
bioactive
elements
drugs
into
therapeutic
explored.
biologically
friendly
be
an
effective
approach
improving
coatings.
Such
enhance
properties
such
as
drug
delivery,
regeneration,
implant
integration,
offering
enormous
potential
patient
welfare.
Future
research
areas
include
investigating
use
advanced
procedures
enhanced
control
over
nanofibre
composition
design
fabrication.
With
the
rapid
development
of
mobile
communication
technology
and
wearable
electronic
devices,
electromagnetic
radiation
generated
by
high-frequency
information
exchange
inevitably
threatens
human
health,
so
high-performance
interference
(EMI)
shielding
materials
are
urgently
needed.
The
2D
nanomaterial
MXene
exhibits
superior
EMI
performance
owing
to
its
high
conductivity,
however,
mechanical
properties
limited
due
porosity
between
nanosheets.
In
recent
years,
it
has
been
reported
that
introducing
natural
nanocellulose
as
an
organic
framework,
MXene/nanocellulose
composites
can
be
synergically
improved,
which
expected
widely
used
in
multifunctional
devices.
this
review,
wave
(EMW)
attenuation
mechanism
is
briefly
introduced,
latest
progress
applications
comprehensively
reviewed,
wherein
advantages
disadvantages
different
preparation
methods
various
types
summarized.
Finally,
challenges
perspectives
discussed,
regarding
improvement,
control
mechanism,
large-scale
production
composites.
This
review
provide
guidance
on
design
flexible
for
protection
future
intelligent
field.
