Advanced Materials,
Год журнала:
2024,
Номер
unknown
Опубликована: Дек. 11, 2024
Biomolecule
isolation
is
a
crucial
process
in
diverse
biomedical
and
biochemical
applications,
including
diagnostics,
therapeutics,
research,
manufacturing.
Recently,
MXenes,
novel
class
of
two-dimensional
nanomaterials,
have
emerged
as
promising
adsorbents
for
this
purpose
due
to
their
unique
physicochemical
properties.
These
biocompatible
antibacterial
nanomaterials
feature
high
aspect
ratio,
excellent
conductivity,
versatile
surface
chemistry.
This
timely
review
explores
the
potential
MXenes
isolating
wide
range
biomolecules,
such
proteins,
nucleic
acids,
small
molecules,
while
highlighting
key
future
research
trends
innovative
applications
poised
transform
field.
provides
an
in-depth
discussion
various
synthesis
methods
functionalization
techniques
that
enhance
specificity
efficiency
biomolecule
isolation.
In
addition,
mechanisms
by
which
interact
with
biomolecules
are
elucidated,
offering
insights
into
selective
adsorption
customized
separation
capabilities.
also
addresses
recent
advancements,
identifies
existing
challenges,
examines
emerging
may
drive
next
wave
innovation
rapidly
evolving
area.
International Journal of Biological Macromolecules,
Год журнала:
2024,
Номер
278, С. 134374 - 134374
Опубликована: Авг. 3, 2024
The
consumption
of
animal
products
has
witnessed
a
significant
increase
over
the
years,
leading
to
growing
need
for
industries
adopt
strict
waste
control
measures
mitigate
environmental
impacts.
disposal
in
landfill
can
result
diverse
and
potentially
hazardous
decomposition
by-products.
Animal
by-products,
derived
from
meat,
poultry,
seafood
fish
industries,
offer
substantial
raw
material
source
collagen
gelatin
production
due
their
high
protein
content.
Collagen,
being
major
component
tissues,
represents
an
abundant
resource
that
finds
application
various
chemical
industries.
demand
collagen-based
continues
grow,
yet
availability
primary
remains
limited
insufficient
meet
projected
needs.
Consequently,
repurposing
materials
contain
provides
opportunity
this
while
at
same
time
minimizing
amount
is
dumped.
This
review
examines
potential
extract
value
content
present
animal-derived
It
systematic
evaluation
different
species
groups
discusses
approaches
processing
fabricating
repurposed
collagen.
specifically
focuses
on
research,
encompassing
examination
its
physical
properties,
as
well
modifications.
We
have
detailed
how
research
knowledge
built
structure
function
will
drive
new
initiatives
lead
development
opportunities
future.
Additionally,
it
highlights
emerging
extracting
high-quality
efforts
fabricate
original
within
chemical,
biomedical
science-based
International Journal of Molecular Sciences,
Год журнала:
2024,
Номер
25(16), С. 8615 - 8615
Опубликована: Авг. 7, 2024
Neural
interfaces
are
crucial
conduits
between
neural
tissues
and
external
devices,
enabling
the
recording
modulation
of
activity.
However,
with
increasing
demand,
simple
no
longer
adequate
to
meet
requirements
for
precision,
functionality,
safety.
There
three
main
challenges
in
fabricating
advanced
interfaces:
sensitivity,
heat
management,
biocompatibility.
The
electrical,
chemical,
optical
properties
2D
nanomaterials
enhance
sensitivity
various
types
interfaces,
while
newly
developed
do
not
exhibit
adverse
reactions
terms
management
Additionally,
can
further
improve
functionality
these
including
magnetic
resonance
imaging
(MRI)
compatibility,
stretchability,
drug
delivery.
In
this
review,
we
examine
recent
applications
focusing
on
their
contributions
enhancing
performance
functionality.
Finally,
summarize
advantages
disadvantages
nanomaterials,
analyze
importance
biocompatibility
testing
propose
that
improving
developing
composite
material
structures
interface
will
continue
lead
forefront
field.
Chemical Society Reviews,
Год журнала:
2025,
Номер
unknown
Опубликована: Янв. 1, 2025
Recent
advancements
in
wearable
biosensors
and
bioelectronics
highlight
biocompatible
conducting
nanocomposite
hydrogels
as
key
components
for
personalized
health
devices
soft
electronics.
Objective:
This
study
aims
to
develop
and
characterize
electroactive
hydrogels
based
on
reduced
bacterial
cellulose
(BC)
Ti3C2T
x
-MXene
for
their
potential
application
in
wound
healing
real-time
monitoring.
Impact
Statement:
The
integration
of
into
BC
matrices
represents
a
novel
approach
creating
multifunctional
that
combine
biocompatibility,
electrical
conductivity,
mechanical
durability.
These
properties
make
the
promising
candidates
advanced
care
monitoring
applications.
Introduction:
Wound
requires
materials
support
cell
growth,
promote
tissue
regeneration,
enable
MXenes,
class
2-dimensional
materials,
offer
unique
properties,
making
them
suitable
biomedical
explores
with
BC,
biopolymer
known
its
excellent
biocompatibility
strength,
create
composite
hydrogel
films
care.
Methods:
was
synthesized
by
etching
Ti3AlC2
hydrofluoric
acid
integrated
pellicles
produced
Gluconacetobacter
xylinum.
underwent
characterization
through
x-ray
diffraction
(XRD),
photoelectron
spectroscopy
(XPS),
Fourier
transform
infrared
(FTIR),
thermogravimetric
analysis
(TGA)
determine
structural,
chemical,
thermal
properties.
Mechanical
testing
assessed
tensile
compressive
strengths.
Biological
assessments,
including
viability,
hemolysis
rate,
protein
expression,
evaluated
regenerative
potential.
Results:
XRD
confirmed
crystallographic
structure
MXene
film.
XPS
FTIR
validated
successful
incorporation
film
matrix.
Composite
demonstrated
strength
3.5
MPa
4.2
MPa.
TGA
showed
stability
up
350
°C,
conductivity
reached
9.14
×
10-4
S/m,
enabling
capabilities.
Cell
viability
exceeded
95%,
rate
below
2%.
Protein
expression
studies
revealed
ability
skin
regeneration
collagen
I,
K10,
K5,
filaggrin
expression.
Conclusion:
BC/MXene
exhibit
important
as
electronic-skin
patches
accelerating
Their
combination
durability,
highlights
promise
Advanced Engineering Materials,
Год журнала:
2025,
Номер
unknown
Опубликована: Март 9, 2025
Smart
textiles
integrated
with
2D
materials
are
revolutionizing
the
field
of
wearable
technologies
by
providing
advanced
functionalities
that
extend
far
beyond
those
traditional
fabrics.
This
review
comprehensively
explores
cutting‐edge
materials,
such
as
graphene
derivatives,
MXenes,
and
transition‐metal
dichalcogenides,
highlights
their
unique
electrical,
mechanical,
thermal
properties.
The
sophisticated
methods
which
these
embedded
into
textiles,
including
coating,
deposition,
3D
printing,
spinning,
other
approaches,
thoroughly
discussed.
is
followed
an
overview
applications
smart
energy
harvesting,
environmental
human
health
monitoring,
storage,
electromagnetic‐interference
shielding,
management,
each
contribute
to
multifaceted
capabilities
modern
wearables.
Finally,
emphasizes
shift
toward
multifunctionality,
through
increasingly
configured
perform
multiple
roles
simultaneously,
thereby
enhancing
both
utility
efficiency
textiles.
By
offering
a
detailed
account
current
achievements
potential
advancements
in
this
underscores
pivotal
role
crafting
next‐generation
wearables
for
healthcare,
sports,
beyond.
MXenes,
a
rapidly
emerging
class
of
two-dimensional
materials,
have
demonstrated
exceptional
versatility
and
functionality
across
various
domains,
including
microbiology
virology.
