Macromolecular Materials and Engineering,
Journal Year:
2025,
Volume and Issue:
unknown
Published: March 13, 2025
Abstract
MXene‐based
materials
have
gained
attention
in
the
biomedical
field
due
to
their
promising
biocompatibility,
improved
mechanical
strength,
and
conductivity.
In
this
study,
focus
is
on
optimizing
MXene‐incorporated
electrospun
fibers
subsequent
characterizations
assess
potential
for
applications.
Polyvinyl
alcohol
(PVA)
used
as
appropriate
matrix
material
process
parameters
are
finetuned
ensure
effective
incorporation
of
MXene.
XRD
spectroscopic
analysis
confirm
successful
synthesis
integration
MXenes
into
nanofibers.
Morphological
shows
that
MXene
led
formation
sub‐micrometer
with
smooth
surfaces
reduced
fiber
diameter
(587
±
191
nm)
compared
pure
PVA
(696
±160
nm).
Investigations
electrical
characteristics
demonstrate
a
fourfold
increase
conductivity
nanofibers
(σ
=
1.90
0.45
×
10
−8
S
cm
−1
)
after
addition
(compared
σ
0.46
0.05
PVA‐only
fibers).
Furthermore,
MXene‐PVA
system
demonstrates
nearly
twofold
stiffness,
E
136.87
19.63
MPa
than
71.42
16.56
PVA.
Moreover,
initial
vitro
experiments
indicate
L929
cell
viability.
These
findings
position
composites
highly
versatile
platform
advanced
devices,
such
electroactive
tissue
scaffolds
wearable
sensors.
Chemical Society Reviews,
Journal Year:
2025,
Volume and Issue:
unknown
Published: Jan. 1, 2025
Recent
advancements
in
wearable
biosensors
and
bioelectronics
highlight
biocompatible
conducting
nanocomposite
hydrogels
as
key
components
for
personalized
health
devices
soft
electronics.
Advanced Functional Materials,
Journal Year:
2025,
Volume and Issue:
unknown
Published: Feb. 9, 2025
Abstract
Hepatocellular
carcinoma
(HCC)
poses
a
formidable
challenge
to
global
health,
and
surgical
resection
is
the
predominant
therapeutic
strategy.
However,
efficacy
of
postoperative
adjuvant
treatments
often
compromised
by
need
preserve
liver
function.
The
authors’
meta‐analysis
reveals
significant
correlation
between
impaired
function
decreased
survival
rates
in
HCC
patients,
highlighting
critical
for
interventions
protect
To
address
this,
an
innovative
injectable
composite
hydrogel
system
engineered,
designated
MC@PHDA,
which
encapsulates
Molybdenum
disulfide
MoS
2
nanozymes
Chlorella
photosensitizers
within
hyaluronic
acid‐dopamine/2‐aminoethyl
methacrylate
(HA‐DA/AMA)
matrix.
This
offers
comprehensive
approach
HCC,
combining
photodynamic
photothermal
therapies
selectively
target
eradicate
cancer
cells;
while,
inducing
immunogenic
cell
death
(ICD)
stimulate
antitumor
immune
response.
MC@PHDA
leverages
ROS‐scavenging
properties
mitigate
oxidative
injury
promote
hepatocyte
regeneration.
Thus,
multifaceted
design
represents
paradigm‐shifting
strategy
treatment
that
targets
tumor
concurrently
promoting
repair
study
introduces
groundbreaking
integrative
management
with
potential
significantly
enhance
patient
quality
life.
Macromolecular Materials and Engineering,
Journal Year:
2025,
Volume and Issue:
unknown
Published: March 13, 2025
Abstract
MXene‐based
materials
have
gained
attention
in
the
biomedical
field
due
to
their
promising
biocompatibility,
improved
mechanical
strength,
and
conductivity.
In
this
study,
focus
is
on
optimizing
MXene‐incorporated
electrospun
fibers
subsequent
characterizations
assess
potential
for
applications.
Polyvinyl
alcohol
(PVA)
used
as
appropriate
matrix
material
process
parameters
are
finetuned
ensure
effective
incorporation
of
MXene.
XRD
spectroscopic
analysis
confirm
successful
synthesis
integration
MXenes
into
nanofibers.
Morphological
shows
that
MXene
led
formation
sub‐micrometer
with
smooth
surfaces
reduced
fiber
diameter
(587
±
191
nm)
compared
pure
PVA
(696
±160
nm).
Investigations
electrical
characteristics
demonstrate
a
fourfold
increase
conductivity
nanofibers
(σ
=
1.90
0.45
×
10
−8
S
cm
−1
)
after
addition
(compared
σ
0.46
0.05
PVA‐only
fibers).
Furthermore,
MXene‐PVA
system
demonstrates
nearly
twofold
stiffness,
E
136.87
19.63
MPa
than
71.42
16.56
PVA.
Moreover,
initial
vitro
experiments
indicate
L929
cell
viability.
These
findings
position
composites
highly
versatile
platform
advanced
devices,
such
electroactive
tissue
scaffolds
wearable
sensors.
