Advanced Materials Technologies,
Год журнала:
2025,
Номер
unknown
Опубликована: Май 30, 2025
Abstract
The
discovery
of
MXenes
has
yielded
several
innovative
approaches
to
manufacturing
conductive
materials
for
improved
performance
in
sectors.
Among
the
various
types
MXenes,
titanium
carbide
MXene
(Ti
3
C
2
T
X
)
is
widely
applied
advanced
material
design
due
its
desirable
characteristics.
Integrating
Ti
with
textiles
promises
create
a
new
generation
textile
enhanced
properties
application
devices,
including
wearable
biomedical
sensors.
It
been
observed
that
as
base
health
sector
not
received
significant
attention,
hence,
there
need
critical
review
allow
greater
insights
into
prospects
using
this
2D
industry
toward
smart
healthcare
delivery.
This
conducted
fill
gap
by
delving
sensor
design.
Findings
show
are
promising
advancing
electronics,
especially
Future
studies
explore
integration
MXenes‐based
biosensors
Internet
Things,
and
methodologies
harmless
environment
human
health,
recommended
ensure
seamless
delivery
sensors
sustainable
manufacturing.
Recently,
flexible
electronics
have
significantly
transformed
information
and
communications
technology
(ICT).
In
particular,
wearable
devices,
via
integration
with
attachable
biosensors,
driven
the
development
of
new
types
biosensors
diagnostic
devices
for
point-of-care
testing
(POCT).
Moreover,
electrochemical
can
be
applied
to
diagnose
diseases
in
real
time
based
on
synergistic
effect
generated
from
incorporation
technique.
Besides,
improve
sensitivity
while
retaining
their
wearability,
novel
nanomaterials
nanotechnologies
been
introduced.
this
review,
recent
studies
nanotechnology-based
accurate
disease
diagnosis
are
discussed.
First,
widely
used
techniques
developing
electrodes,
including
nanolithography-
nano/microneedle-based
patches,
presented.
Next,
latest
such
as
diabetes
dermatitis
discussed
by
categorizing
into
categories.
Finally,
review
explores
research
trends
application
nanotechnology-enabled
nanopatterning
nano/microneedle
technologies
biosensors.
This
suggests
approaches
methods
real-time
under
POCT
applications.
Abstract
Biosensors
are
analytical
tools
that
integrate
a
biological
element
with
physicochemical
detector
in
order
to
quantify
the
existence
or
concentration
of
chemicals,
biomolecules,
other
elements
for
human
health
monitoring
purposes.
Electrochemical
techniques
analyte
detection
include
use
electrochemical
sensors
identify
and
molecules.
These
often
used
because
their
high
sensitivity,
specificity,
quick
reaction
time,
possibility
being
made
smaller
size,
but
still,
research
problem
electrochemical‐based
biosensing
largely
revolves
around
improving
biosensors′
selectivity,
stability,
response
time.
Borophene,
an
intriguing
novel
substance
within
domain
two‐dimensional
(2D)
materials,
emerges
as
highly
promising
protagonist
continuous
dynamic
history
nanoscience
nanotechnology.
characterized
by
its
distinctive
electronic,
mechanical,
thermal
properties,
enthralls
scientists
due
atomic
structure
consisting
exclusively
boron
atoms
organized
honeycomb
lattice.
In
recent
years,
borophene
hybrids
composites
have
emerged
potentially
fruitful
avenues
expanding
utility
numerous
fields
properties.
addition,
hybrid
systems
hold
significant
potential
overcome
limitations
current
biosensors.
By
leveraging
unique
properties—such
surface
area,
chemical
versatility,
mechanical
strength—these
materials
can
improve
limitations.
Moreover,
integration
further
optimize
performance,
paving
way
advanced
practical
solutions.
This
perspective
presents
synopsis
developments
based
on
borophene,
including
polymers
nanomaterials.
we
emphasized
remarkable
characteristics
hybrids,
which
permit
analytes
such
proteins,
nucleic
acids,
small
molecules
sensitive
selective
manner.
Additionally,
summary
computational
investigations
into
utilizing
borophene‐based
has
been
provided.
nutshell,
discussed
challenges
future
directions
field,
outlining
opportunities
innovation
optimization
platforms.
ACS Nano,
Год журнала:
2024,
Номер
18(46), С. 31713 - 31736
Опубликована: Ноя. 7, 2024
Sensitive
and
quantitative
detection
of
chemical
biological
molecules
for
screening,
diagnosis
monitoring
diseases
is
essential
to
treatment
planning
response
monitoring.
Electrochemical
biosensors
are
fast,
sensitive,
easy
miniaturize,
which
has
led
rapid
development
in
clinical
diagnosis.
Benefiting
from
their
excellent
molecular
recognition
ability
high
programmability,
DNA
nanomaterials
could
overcome
the
Debye
length
electrochemical
by
simple
design
well
suited
as
elements
biosensors.
Therefore,
enhance
sensitivity
specificity
biosensors,
significant
progress
been
made
recent
years
optimizing
design.
Here,
establishment
sensing
strategies
based
on
reviewed
detail.
First,
structural
nanomaterial
examined
improving
overcoming
length.
In
addition,
electrical
signal
transduction
amplification
reviewed,
applications
nanomaterial-based
integrated
devices
further
summarized.
Finally,
main
opportunities
challenges
detecting
disease
biomarkers
presented
an
aim
guide
with
specificity.
Biosensors and Bioelectronics,
Год журнала:
2024,
Номер
263, С. 116632 - 116632
Опубликована: Авг. 3, 2024
Microfluidic
devices
are
increasingly
widespread
in
the
literature,
being
applied
to
numerous
exciting
applications,
from
chemical
research
Point-of-Care
devices,
passing
through
drug
development
and
clinical
scenarios.
Setting
up
these
microenvironments,
however,
introduces
necessity
of
locally
controlling
variables
involved
phenomena
under
investigation.
For
this
reason,
literature
has
deeply
explored
possibility
introducing
sensing
elements
investigate
physical
quantities
biochemical
concentration
inside
microfluidic
devices.
Biosensors,
particularly,
well
known
for
their
high
accuracy,
selectivity,
responsiveness.
However,
signals
could
be
challenging
interpret
must
carefully
analysed
carry
out
correct
information.
In
addition,
proper
data
analysis
been
demonstrated
even
increase
biosensors'
mentioned
qualities.
To
regard,
machine
learning
algorithms
undoubtedly
among
most
suitable
approaches
undertake
job,
automatically
highlighting
biosensor
signals'
characteristics
at
best.
Interestingly,
it
was
also
benefit
themselves,
a
new
paradigm
that
is
starting
name
"intelligent
microfluidics",
ideally
closing
benefic
interaction
disciplines.
This
review
aims
demonstrate
advantages
triad
microfluidics-biosensors-machine
learning,
which
still
little
used
but
great
perspective.
After
briefly
describing
single
entities,
different
sections
will
benefits
dual
interactions,
applications
where
reviewed
employed.
The
emerging
integrated
power
supplies
for
self-powered
bioelectronic
devices
over
the
past
few
years
are
summarized.
Additionally,
challenges
and
future
perspectives
in
device
design
manufacturing
also
indicated.
LWT,
Год журнала:
2024,
Номер
206, С. 116567 - 116567
Опубликована: Июль 29, 2024
Rapid
and
accurate
detection
of
pathogenic
bacteria
is
crucial
for
ensuring
food
safety
public
health.
In
this
study,
we
aimed
to
develop
a
novel
molecularly
imprinted
polymer
sensor
based
on
screen-printed
electrodes
the
specific
Salmonella
typhimurium.
The
was
constructed
by
electropolymerizing
dopamine
in
presence
typhimurium
electrode
surface,
followed
removal
create
binding
cavities.
demonstrated
excellent
specificity
typhimurium,
with
limit
approximately
101
CFU/ml
time
only
4
min,
accurately
differentiating
from
other
common
foodborne
pathogens
such
as
Escherichia
coli
Listeria
monocytogenes.
performance
validated
using
real
samples,
including
pork
milk,
showing
its
well
suited
rapid
on-site
bacteria.
development
electrochemical
represents
significant
advancement
field
biosensors,
offering
promising
tool
monitoring
health
protection.
