ChemElectroChem,
Journal Year:
2025,
Volume and Issue:
unknown
Published: April 1, 2025
Herein,
the
basic
properties,
composition,
and
isolation
methods
for
separation
of
exosomes
are
described,
since
they
can
be
a
rich
source
disease
biomarkers.
Then
an
introduction
to
MXenes,
novel
class
2D
nanomaterials
with
interesting
properties
applicable
in
numerous
fields
including
biosensing
is
provided.
Also,
aptamers
described
as
alternative
antibodies
robust
biorecognition
analytes
interest.
The
final
part
article
gives
examples
which
these
three
key
components
integrated
sensitive
and/or
electrochemical
detection
exosomes.
conclusion
provides
summary
initial
achievements
also
outlook
future
discoveries
exosome
aptasensing
using
advanced
nanomaterials,
i.e.,
MXenes.
MXenes
have
promising
affinity‐based
biosensing,
being
hydrophilic
surface
functional
groups.
In
addition,
free
plasmons
present
used
covalent
grafting
elements
diazonium
moieties.
This
especially
approach
immobilization
DNA/RNA
aptamers,
readily
modified
by
Advanced Materials Interfaces,
Journal Year:
2025,
Volume and Issue:
unknown
Published: April 4, 2025
Abstract
The
increasing
reliance
on
nuclear
energy
as
a
significant
low‐carbon
power
source
necessitates
effective
solutions
for
managing
radioactive
emissions.
This
study
introduces
novel
application
of
MXene
nanohybrids,
specifically
silver‐MXene
(Ag‐Ti
3
C
2
T
x
),
an
sorbent
radioiodine
off‐gas
capture
at
operating
temperature
150
°C.
Through
comprehensive
material
characterization,
including
X‐ray
diffraction,
scanning
and
transmission
electron
microscopies,
energy‐dispersive
spectroscopy,
Raman
thermogravimetric
analysis,
inductively
coupled
plasma
optical
emission
gas
sorption
analyses,
the
successful
loading
Ag
nanoparticles
onto
Ti
is
confirmed
subsequent
formation
AgI
upon
iodine
capture.
results
demonstrate
that
Ag‐Ti
exhibits
superior
uptake
compared
to
traditional
silver‐based
sorbents
such
silver
mordenite
zeolite
(AgZ)
silver‐functionalized
silica
aerogel
(AgAero).
achieves
946
mg
g
−1
,
significantly
outperforming
AgZ
(131
).
These
findings
highlight
potential
highly
efficient,
thermally
stable
capture,
potentially
addressing
key
limitations
existing
materials.
Polymers for Advanced Technologies,
Journal Year:
2024,
Volume and Issue:
35(12)
Published: Nov. 29, 2024
ABSTRACT
MXene‐based
hydrogels
represent
a
significant
advancement
in
biomedical
material
science,
leveraging
the
unique
properties
of
2D
MXenes
and
versatile
functionality
hydrogels.
This
review
discusses
recent
developments
integration
into
hydrogel
matrices,
focusing
on
their
applications
such
as
wound
healing,
drug
delivery,
antimicrobial
activity,
tissue
engineering,
biosensing.
MXenes,
due
to
remarkable
electrical
conductivity,
mechanical
robustness,
tunable
surface
chemistry,
enhance
properties,
responsiveness
environmental
stimuli.
Specifically,
have
shown
great
promise
accelerating
healing
through
photothermal
effects,
delivering
drugs
controlled
manner,
serving
antibacterial
agents.
Their
also
enables
targeted
cancer
therapies,
including
chemodynamic
facilitated
by
high
conductivity
properties.
Despite
promising
progress,
challenges
ensuring
biocompatibility
optimizing
synthesis
for
large‐scale
production
remain.
aims
provide
comprehensive
overview
current
state
applications,
highlighting
ongoing
advancements
potential
future
directions
these
multifunctional
materials.
