ACS Applied Materials & Interfaces,
Journal Year:
2022,
Volume and Issue:
14(5), P. 7301 - 7310
Published: Jan. 25, 2022
The
high
moisture
level
of
exhaled
gases
unavoidably
limits
the
sensitivity
breath
analysis
via
wearable
bioelectronics.
Inspired
by
pulmonary
lobe
expansion/contraction
observed
during
respiration,
a
respiration-driven
triboelectric
sensor
(RTS)
was
devised
for
simultaneous
respiratory
biomechanical
monitoring
and
acetone
concentration
analysis.
A
tin
oxide-doped
polyethyleneimine
membrane
to
play
dual
role
as
both
layer
an
sensing
material.
prepared
RTS
exhibited
excellent
ability
in
measuring
flow
rate
(2-8
L/min)
frequency
(0.33-0.8
Hz).
Furthermore,
presented
good
performance
biochemical
(2-10
ppm
range
at
levels),
which
validated
finite
element
This
work
has
led
development
novel
real-time
active
system
strengthened
triboelectric-chemisorption
coupling
mechanism.
Materials Today Bio,
Journal Year:
2023,
Volume and Issue:
19, P. 100565 - 100565
Published: Jan. 28, 2023
Sedentary
lifestyles
and
evolving
work
environments
have
created
challenges
for
global
health
cause
huge
burdens
on
healthcare
fitness
systems.
Physical
immobility
functional
losses
due
to
aging
are
two
main
reasons
noncommunicable
disease
mortality.
Smart
electronic
textiles
(e-textiles)
attracted
considerable
attention
because
of
their
potential
uses
in
monitoring,
rehabilitation,
training
assessment
applications.
Interactive
integrated
with
devices
algorithms
can
be
used
gather,
process,
digitize
data
human
body
motion
real
time
purposes
such
as
electrotherapy,
improving
blood
circulation,
promoting
wound
healing.
This
review
summarizes
research
advances
e-textiles
designed
wearable
The
significance
e-textiles,
key
applications,
future
demand
expectations
addressed
this
review.
Various
conditions
problems
possible
solutions
involving
the
use
multifunctional
interactive
garments
discussed.
A
brief
discussion
essential
materials
basic
procedures
fabricate
included.
Finally,
current
challenges,
solutions,
opportunities,
perspectives
area
smart
ACS Nano,
Journal Year:
2022,
Volume and Issue:
16(9), P. 13301 - 13313
Published: Aug. 15, 2022
At
the
forefront
of
smart
textile
community,
healthcare
and
sustainability
are
two
crucial
objectives
targeted
by
researchers.
The
development
such
powerful
devices
has
been
driven
innovative
fabrications
breathable,
skin-conformable
technologies
through
use
functional
programmable
materials
device
structures.
This
Perspective
focuses
on
current
textiles
available
in
research
field,
categorized
into
personalized
healthcare,
including
diagnostics
therapeutics,
sustainability,
energy
harvesting
conservation─personalized
thermoregulation.
These
categories
further
broken
down
their
platform
structural
performances.
Furthermore,
we
give
a
comprehensive
overview
highlight
few
examples
studies.
Finally,
provide
an
outlook
these
for
future
researchers
to
participate.
We
envision
that
next
generation
will
revolutionize
wearable
technology
sustainability.
Advanced Functional Materials,
Journal Year:
2022,
Volume and Issue:
32(35)
Published: June 15, 2022
Abstract
Infants
are
physically
vulnerable
and
cannot
express
their
feelings.
Continuous
monitoring
measuring
the
biomechanical
pressure
to
which
an
infant
body
is
exposed
remains
critical
avoid
injury
illness.
Here,
a
area
sensor
network
comprising
edible
triboelectric
hydrogel
sensors
for
all‐around
motion
reported.
Each
soft
holds
collection
of
compelling
features
high
signal‐to‐noise
ratio
23.1
dB,
sensitivity
0.28
V
kPa
−1
,
fast
response
time
50
ms.
With
assistance
deep
learning
algorithms,
can
realize
pattern
identification
recognition
with
classification
accuracy
as
100%.
Additionally,
customized
user‐friendly
cellphone
application
developed
provide
real‐time
warning
one‐click
guardian
interaction.
This
self‐powered
system
provides
promising
paradigm
reliable
care
in
era
Internet
Things.
ACS Applied Materials & Interfaces,
Journal Year:
2022,
Volume and Issue:
14(5), P. 7301 - 7310
Published: Jan. 25, 2022
The
high
moisture
level
of
exhaled
gases
unavoidably
limits
the
sensitivity
breath
analysis
via
wearable
bioelectronics.
Inspired
by
pulmonary
lobe
expansion/contraction
observed
during
respiration,
a
respiration-driven
triboelectric
sensor
(RTS)
was
devised
for
simultaneous
respiratory
biomechanical
monitoring
and
acetone
concentration
analysis.
A
tin
oxide-doped
polyethyleneimine
membrane
to
play
dual
role
as
both
layer
an
sensing
material.
prepared
RTS
exhibited
excellent
ability
in
measuring
flow
rate
(2-8
L/min)
frequency
(0.33-0.8
Hz).
Furthermore,
presented
good
performance
biochemical
(2-10
ppm
range
at
levels),
which
validated
finite
element
This
work
has
led
development
novel
real-time
active
system
strengthened
triboelectric-chemisorption
coupling
mechanism.
