Advanced Physics Research,
Год журнала:
2025,
Номер
unknown
Опубликована: Фев. 4, 2025
Abstract
Bioelectronics,
which
integrate
biological
systems
with
electronic
components,
have
attracted
significant
attention
in
developing
biomimetic
materials
and
advanced
hardware
architectures
to
enable
novel
information‐processing
systems,
sensors,
actuators.
However,
the
rigidity
of
conjugated
molecular
lack
reconfigurability
static
crosslinked
structures
pose
challenges
for
flexible
sensing
applications.
Topological
networks
(TCNs)
featuring
dynamic
interactions
offer
enhanced
flexibility
environmentally
induced
reconfigurability,
decoupling
competition
between
performances.
Here,
recent
advances
are
summarized
assembly
methods
bioelectronics
different
TCNs
elaborate
ion/electron‐transport
mechanisms
from
perspective
interactions.
Decoupling
effects
can
be
achieved
by
comparing
distinct
their
respective
properties,
an
outlook
is
provided
on
a
new
range
neuromorphic
biocompatibility,
self‐healing,
self‐powered,
multimodal‐sensing
capabilities.
The
development
TCN‐based
significantly
impact
fields
artificial
perception
devices,
networks,
systems.
Advanced Science,
Год журнала:
2025,
Номер
unknown
Опубликована: Фев. 4, 2025
Abstract
A
fibrous
flexible
sensor,
with
its
small
size,
minimally
burdens
the
human
body,
ranking
among
most
user‐friendly
sensors.
However,
application
is
often
limited
by
damage
caused
electrode
movement,
as
sensors
are
typically
attached
to
joints,
which
can
be
greatly
alleviated
placing
two
electrodes
on
same
side.
Inspired
hydrogen
bonds
in
double‐helical
structure
of
DNA,
design
commonly
found
and
applied
fiber‐based
batteries
supercapacitors
into
through
coaxial
wet‐spinning
further
treatment.
The
double
helical
sensor
exhibits
high
strength
maintains
stable
operation
prepared
under
over
300%
strain
gauge
factors
(GF)
0.9,
39.5,
349,
respectively,
working
ranges.
This
unique
single‐sided
also
enabled
applications
such
water
flow
sensing.
a
smart
glove
capable
real‐time
integrated,
five‐channel
finger
motion
detection,
used
convolutional
neural
network
(CNN)‐based
machine
learning
algorithm
achieve
98.8%
accuracy
recognizing
six
common
gestures.
study
provides
novel
approach
optimize
distribution
an
internally
encapsulated
structure,
making
significant
contribution
field
Advanced Healthcare Materials,
Год журнала:
2025,
Номер
unknown
Опубликована: Фев. 9, 2025
To
overcome
the
limitations
of
precise
monitoring
and
inefficient
wound
exudate
management
in
healing,
an
advanced
multifunctional
hydrogel
electronics
(MHE)
platform
based
on
MXene@MOF/Fe3O4@C
photonic
crystal
is
developed.
This
combines
optical/electrical
sensing,
synergistic
therapy,
real-time
visual
into
a
single,
efficient
system,
offering
comprehensive
solution
for
healing.
Under
photothermal
stimulation,
releases
metal
ions
that
generate
hydroxyl
radicals,
effectively
eliminating
antibiotic-resistant
bacteria.
Beyond
its
antibacterial
efficacy,
this
system
offers
unprecedented
through
temperature-responsive
visualization,
while
structural
color
changes
upon
absorption
provide
clear
indication
dressing
replacement.
By
integrating
these
functionalities,
MHE
allows
control
therapeutic
process,
significantly
improving
healing
treatment
monitoring.
The
platform's
sensing
capabilities
further
broaden
potential
applications
across
other
biomedical
fields.
breakthrough
technology
provides
clinicians
with
powerful
tool
to
optimize
outcomes,
marking
major
advancement
care
applications.
Nanomaterials,
Год журнала:
2025,
Номер
15(4), С. 298 - 298
Опубликована: Фев. 15, 2025
Flexible
sensors
are
revolutionizing
our
lives
as
a
key
component
of
intelligent
wearables.
Their
pliability,
stretchability,
and
diverse
designs
enable
foldable
portable
devices
while
enhancing
comfort
convenience.
Advances
in
materials
science
have
provided
numerous
options
for
creating
flexible
sensors.
The
core
their
application
areas
like
electronic
skin,
health
medical
monitoring,
motion
human-computer
interaction
is
selecting
that
optimize
sensor
performance
weight,
elasticity,
comfort,
flexibility.
This
article
focuses
on
sensors,
analyzing
"sensing
mechanisms-materials-applications"
framework.
It
explores
development
trajectory,
material
characteristics,
contributions
various
domains
such
interaction.
concludes
by
summarizing
current
research
achievements
discussing
future
challenges
opportunities.
expected
to
continue
expanding
into
new
fields,
driving
the
evolution
smart
wearables
contributing
society.
Electrically
conductive
hydrogels
are
highly
hydrated
3D
networks
consisting
of
a
hydrophilic
polymer
skeleton
and
electrically
materials.
Conductive
have
excellent
mechanical
electrical
properties
further
extensive
application
prospects
in
biomedical
treatment
other
fields.
Whereas
numerous
been
fabricated,
set
general
principles,
that
can
rationally
guide
the
synthesis
using
different
substances
fabrication
methods
for
various
scenarios,
remain
central
demand
hydrogels.
This
paper
systematically
summarizes
processing,
performances,
applications
hydrogels,
discusses
challenges
opportunities
this
field.
In
view
shortcomings
high
conductivity,
matchable
properties,
as
well
integrated
devices
machines,
it
is
proposed
to
synergistically
design
process
with
complex
surroundings.
It
believed
will
present
fresh
perspective
research
development
expand
