Communications Materials,
Год журнала:
2024,
Номер
5(1)
Опубликована: Июнь 12, 2024
Abstract
Overcoming
the
mechanical
disparities
between
implantable
neural
electrodes
and
biological
tissue
is
crucial
in
mitigating
immune
responses,
reducing
shear
motion,
ensuring
durable
functionality.
Emerging
hydrogel-based
interfaces,
with
their
volumetric
capacitance,
customizable
conductivity,
tissue-mimicking
properties,
offer
a
more
efficient,
less
detrimental,
chronically
stable
alternative
to
rigid
counterparts.
Here,
we
provide
an
overview
of
exceptional
advantages
hydrogels
for
development
next-generation
interfaces
highlight
recent
advancements
that
are
transforming
field.
Conductive
flexible
hydrogels
have
attracted
immense
attentions
recently
due
to
their
wide
applications
in
wearable
sensors.
However,
the
poor
mechanical
properties
of
most
conductive
polymer
limit
utilizations.
Herein,
a
double
network
hydrogel
is
fabricated
via
self-sorting
process
with
cationic
polyacrylamide
as
first
and
lantern[3
Advanced Science,
Год журнала:
2024,
Номер
unknown
Опубликована: Сен. 19, 2024
Abstract
Functional
coatings,
including
organic
and
inorganic
play
a
vital
role
in
various
industries
by
providing
protective
layer
introducing
unique
functionalities.
However,
its
design
often
involves
time‐consuming
experimentation
with
multiple
materials
processing
parameters.
To
overcome
these
limitations,
data‐driven
approaches
are
gaining
traction
science.
In
this
paper,
recent
advances
research
development
(R&D)
for
functional
highlighting
the
importance,
data
sources,
working
processes,
applications
of
paradigm
summarized.
It
is
begun
discussing
challenges
traditional
methods,
then
introduce
typical
processes.
demonstrated
how
enable
identification
correlations
between
input
parameters
coating
performance,
thus
allowing
efficient
prediction
design.
Furthermore,
carefully
selected
case
studies
presented
across
diverse
that
exemplify
effectiveness
methods
accelerating
discovery
new
coatings
tailored
properties.
Finally,
emerging
directions,
involving
integrating
advanced
techniques
from
different
addressed.
Overall,
review
provides
an
overview
R&D
shedding
light
on
potential
future
developments.
Advanced Functional Materials,
Год журнала:
2025,
Номер
unknown
Опубликована: Фев. 26, 2025
Abstract
Driven
by
the
growing
burden
of
chronic
diseases
and
limited
public
healthcare
resources,
portable
health
monitoring
platforms
are
widely
developed
to
enable
continuous
timely
dissemination
provide
users
with
management
disease
prevention.
However,
it
is
still
a
challenge
for
precision
fully
bio‐integrated
electronic
devices
achieve
stable
physiological
signal
recording
over
long
periods
time.
Recently,
semi‐implantable
bioelectronics
(SI‐bioelectronics)
have
excelled
in
real‐time,
long‐term,
high‐sensitivity
pathological
signals
minimal
invasiveness,
enabled
precise
microneedle
sensing
probes.
In
this
review,
comprehensive
overview
recent
advancements
SI‐bioelectronics
provided,
focus
on
their
structures,
design
considerations,
performances
biochemical
indicators,
bioelectrical
signals,
biomechanical
signals.
Opportunities
research
such
as
smart
medicine
Internet
Things
also
discussed,
which
will
drive
toward
intelligence
efficiency.
Small Structures,
Год журнала:
2025,
Номер
unknown
Опубликована: Март 27, 2025
Conductive
hydrogels
provide
a
flexible
platform
technology
that
enables
the
development
of
personalized
materials
for
various
neuronal
diagnostic
and
therapeutic
applications,
combining
complementary
properties
conductive
hydrogels.
By
ensuring
conductivity
through
materials,
largely
compensate
rigidity
traditional
inorganic
making
them
suitable
substitute.
To
adapt
to
different
working
environments,
exhibit
excellent
properties,
such
as
mechanical
adhesion,
biocompatibility,
which
further
expand
their
applications.
This
review
summarizes
fabrication
methods,
applications
in
neural
interfaces.
Finally,
prevailing
challenges
outlines
future
directions
field
interfaces
are
provided,
emphasizing
need
interdisciplinary
research
address
issues
long‐term
stability
scalability
production.
Communications Materials,
Год журнала:
2024,
Номер
5(1)
Опубликована: Июнь 12, 2024
Abstract
Overcoming
the
mechanical
disparities
between
implantable
neural
electrodes
and
biological
tissue
is
crucial
in
mitigating
immune
responses,
reducing
shear
motion,
ensuring
durable
functionality.
Emerging
hydrogel-based
interfaces,
with
their
volumetric
capacitance,
customizable
conductivity,
tissue-mimicking
properties,
offer
a
more
efficient,
less
detrimental,
chronically
stable
alternative
to
rigid
counterparts.
Here,
we
provide
an
overview
of
exceptional
advantages
hydrogels
for
development
next-generation
interfaces
highlight
recent
advancements
that
are
transforming
field.
