Advanced Science,
Journal Year:
2024,
Volume and Issue:
11(30)
Published: June 13, 2024
Abstract
Perspiration
plays
a
pivotal
role
not
only
in
thermoregulation
but
also
reflecting
the
body's
internal
state
and
its
response
to
external
stimuli.
The
up‐to‐date
skin‐based
wearable
platforms
have
facilitated
monitoring
simultaneous
analysis
of
sweat,
offering
valuable
physiological
insights.
Unlike
conventional
passive
sweating,
dynamic
normal
perspiration,
which
occurs
during
various
activities
rest
periods,
necessitates
more
reliable
method
collection
accurately
capture
real‐time
fluctuations.
An
innovative
microfluidic
patch
incorporating
hierarchical
superhydrophilic
biosponge,
poise
significantly
improve
efficiency
sweat
is
introduced.
seamlessly
integrated
biosponge
microchannel
showcases
exceptional
absorption
capabilities,
efficiently
capturing
non‐sensitive
exuding
from
skin
surface,
mitigating
sample
loss
minimizing
volatilization.
Furthermore,
incorporation
sweat‐rate
sensors
alongside
suite
functional
electrochemical
endows
uninterrupted
activities,
stress
events,
high‐energy
intake,
other
scenarios.
Nanomaterials,
Journal Year:
2024,
Volume and Issue:
14(17), P. 1398 - 1398
Published: Aug. 27, 2024
Electrophysiological
monitoring
is
a
commonly
used
medical
procedure
designed
to
capture
the
electrical
signals
generated
by
body
and
promptly
identify
any
abnormal
health
conditions.
Wearable
sensors
are
of
great
significance
in
signal
acquisition
for
electrophysiological
monitoring.
Traditional
devices
often
bulky
have
many
complex
accessories
thus,
only
suitable
limited
application
scenarios.
Hydrogels
optimized
based
on
nanomaterials
lightweight
with
excellent
stretchable
properties,
solving
problem
high-quality
wearable
sensors.
Therefore,
development
hydrogels
brings
tremendous
potential
physiological
This
review
first
introduces
latest
advancement
made
from
different
nanomaterials,
such
as
nanocarbon
materials,
nanometal
two-dimensional
transition
metal
compounds,
Second,
versatile
properties
these
composite
hydrogel
reviewed.
Then,
their
applications
various
monitoring,
electrocardiogram
electromyographic
analysis,
electroencephalogram
discussed.
Finally,
current
status
future
prospects
nanomaterial-optimized
summarized.
We
hope
this
will
inspire
using
nanomaterial-based
hydrogels.
Pharmaceutics,
Journal Year:
2024,
Volume and Issue:
16(8), P. 972 - 972
Published: July 23, 2024
Cancer
remains
a
highly
lethal
disease
globally.
The
approach
centered
on
REDOX-targeted
mitochondrial
therapy
for
cancer
has
displayed
notable
benefits.
Plant
polyphenols
exhibit
strong
REDOX
and
anticancer
properties,
particularly
by
affecting
function,
yet
their
structural
instability
low
bioavailability
hinder
utility.
To
overcome
this
challenge,
researchers
have
utilized
the
inherent
physical
chemical
characteristics
of
derivatives
to
develop
innovative
nanomedicines
targeting
mitochondria.
This
review
examines
construction
strategies
properties
various
types
polyphenol-based
biological
nanomedicine
regulating
mitochondria
in
recent
years,
such
as
polyphenol
self-assembly,
metal–phenol
network,
polyphenol–protein,
polyphenol–hydrogel,
polyphenol–chitosan,
polyphenol–liposome.
These
polyphenolic
incorporate
enhanced
features
improved
solubility,
efficient
photothermal
conversion
capability,
regulation
homeostasis,
ion
adsorption
through
diverse
strategies.
focus
is
how
these
promote
ROS
production
mechanism
inhibit
cancer.
Furthermore,
it
delves
into
benefits
applications
treatments,
well
challenges
future
research.
Advanced Functional Materials,
Journal Year:
2025,
Volume and Issue:
unknown
Published: Jan. 10, 2025
Abstract
Self‐driven
water/oil
separation
is
an
effective
and
sustainable
strategy
for
oil
dehydration,
regulating
the
pore
structure
of
materials
to
break
trade‐off
effect
between
flux
retention
remains
a
challenge.
Inspired
by
tip‐to‐base
conduit
widening
vascular
bundle,
enthalpy‒entropy
co‐driven
based
on
tannin/amylose
non‐covalent
self‐assembly
borate
ester
dynamic
crosslinking
innovatively
proposed
constructing
gradient
porous
biomass
aerogel
(termed
as
Si@TAP‐B),
realizing
synchronous
improvement
rate.
The
permeation
fluxes
mixture
water‐in‐oil
emulsion
Si@TAP‐B
achieve
17914.7
10285.6
L
m
−2
h
−1
,
respectively,
rates
remain
above
99%.
asymmetric
solvent
transport
induced
optimizes
hydraulic
resistance
breaks
retention.
Therefore,
under
forward
osmosis
(from
large
pores
small
pores)
twice
that
reverse
osmosis.
Additionally,
similar
self‐healing
ability
plants,
can
restore
original
function
after
severe
damage
through
reversible
bonds
flow
low
surface
energy
materials.
Overall,
this
novel
desirable
developing
biodegradable,
efficient,
durable
with
unique
structures
functions.
Advanced Materials,
Journal Year:
2025,
Volume and Issue:
unknown
Published: Feb. 3, 2025
Abstract
Solid‐state
photosynthetic
cell
factories
(SSPCFs)
are
a
new
production
concept
that
leverages
the
innate
abilities
of
microbes
to
drive
valuable
chemicals.
It
addresses
practical
challenges
such
as
high
energy
and
water
demand
improper
light
distribution
associated
with
suspension‐based
culturing;
however,
these
systems
often
face
significant
related
mass
transfer.
The
approach
focuses
on
overcoming
limitations
by
carefully
engineering
microstructure
immobilization
matrix
through
freeze‐induced
assembly
nanochitin
building
blocks.
use
nanochitins
optimized
size
enabled
formation
macropores
lamellar
spatial
organization,
which
significantly
improves
transmittance
distribution,
crucial
for
maximizing
efficiency
reactions.
biomimetic
crosslinking
strategy,
leveraging
specific
interactions
between
polyphosphate
anions
primary
amine
groups
featured
chitin
fibers,
produced
mechanically
robust
wet‐resilient
cryogels
maintained
their
functionality
under
operational
conditions.
Various
model
biotransformation
reactions
leading
value‐added
chemicals
performed
in
chitin‐based
matrix.
demonstrates
superior
or
comparable
performance
existing
state‐of‐the‐art
matrices
systems.
findings
suggest
cryogel
holds
promise
advancing
development
solid‐state
factories,
offering
scalable
solution
improve
productivity
light‐driven
biotransformation.
