2021 IEEE International Symposium on Smart Electronic Systems (iSES),
Journal Year:
2023,
Volume and Issue:
unknown, P. 437 - 440
Published: Dec. 18, 2023
The
paper
explores
a
novel
approach
to
health
care
using
Machine
Learning
and
the
Internet
of
Things
(IoT)
create
non-invasive
real-time
monitoring
system.
system
uses
IoT
devices
like
wearable
sensors,
smart
medical
devices,
mobile
applications
collect
health-related
data,
including
vital
signs,
activity
levels,
sleep
patterns,
environmental
factors.
This
data
is
integrated
into
centralized
cloud-based
platform
for
accessibility
security.
algorithms
are
used
process
interpret
detecting
anomalies
predicting
potential
issues.
allows
personalized
insights
early
intervention
in
preventive
healthcare.
supports
user-friendly
interfaces,
allowing
individuals
actively
engage
their
own
management.
Patients,
caregivers,
healthcare
professionals
can
access
intuitive
dashboards
receive
notifications
or
alerts
when
abnormalities
detected,
promoting
informed
decision-making
timely
interventions.
Smart
Non-Invasive
Real-Time
Health
Monitoring
has
transform
industry
by
changing
emphasis
from
responding
illnesses
after
they
occur
preventing
them
beforehand.
Materials Today Electronics,
Journal Year:
2023,
Volume and Issue:
5, P. 100055 - 100055
Published: Aug. 11, 2023
As
personal
portable
devices,
wearable
sensors
supply
a
leading-edge
pathway
to
diagnose
various
diseases
through
actuating
biological,
physical,
and
chemical
sensing
capabilities.
This
could
be
commonly
carried
out
via
recording
continuous
real-time
of
the
patient's
physiological
statuses,
as
well
pathophysiological
information.
Although
sensor
technology
is
in
infancy
stage,
tremendous
attempts
have
been
devoted
approaching
flexible
polymeric
sensors.
Among
polymer
candidates
applicable
for
synthesizing
sensors,
bio-based
ones
piqued
more
interest
due
their
biocompatibility,
biodegradability,
eco-friendly
features,
cost-effectiveness.
Additionally,
several
fabrication
techniques
professed
architect
efficient
frameworks,
such
films,
hydrogels,
aerogels,
ferrogels,
3D
layers,
electrospun
mats,
textiles.
In
this
review,
different
mechanisms
declared
engineer
are
overviewed.
Then,
regarding
advantages
observed
polymers,
focused
studies
on
natural-based
described.
Notably,
cellulose,
chitosan,
silk,
gelatin,
alginate's
role
functionality
highlighted.
Accordingly,
review
has
opened
new
window
ahead
opportunities
based
natural
polymers.
It
hoped
that
generation
will
launched
by
combining
emerging
achievements
obtained
from
employing
sustainable
green
elements
miniaturized
structures.
ACS Applied Materials & Interfaces,
Journal Year:
2024,
Volume and Issue:
16(7), P. 8333 - 8345
Published: Feb. 7, 2024
With
the
advantages
of
high
flexibility,
strong
real-time
monitoring
capabilities,
and
convenience,
wearable
devices
have
shown
increasingly
powerful
application
potential
in
medical
rehabilitation,
health
monitoring,
Internet
Things,
human–computer
interaction.
In
this
paper,
we
propose
a
novel
optical
microfiber
intelligent
sensor
based
on
wavy-shaped
polymer
(WPOMF)
for
cardiorespiratory
behavioral
humans.
The
fibers
materials
are
prepared
into
microfibers,
fully
using
material
microfibers.
is
designed
flexible
wave-shaped
structure,
which
enables
WPOMF
to
higher
tensile
properties
detection
sensitivity.
Cardiorespiratory
experiments
successfully
performed,
demonstrates
sensitivity
stability
when
performing
tasks.
Further,
success
AI-assisted
keyword
pronunciation
recognition
experiment
feasibility
integrating
AI
technology
with
sensor,
can
effectively
improve
intelligence
as
device.
As
an
offers
broad
prospects
disease
rehabilitation
medicine,
other
fields.
Communications Materials,
Journal Year:
2024,
Volume and Issue:
5(1)
Published: April 11, 2024
Abstract
Wearable
skin-contacting
devices
are
extensively
studied
for
their
ability
to
provide
convenient
and
safe
health
monitoring.
A
key
aspect
that
controls
performance
the
properties
of
device
electrodes.
Optimizing
electrode
structure,
materials
they
made
from,
can
improve
functionality.
Here,
we
discuss
various
required
optimal
performance,
including
mechanical,
electrical,
biocompatible
factors.
To
address
these
challenges,
consider
alteration
development
flexible
or
soft
conductive
materials,
creation
hybrid
structures.
Additionally,
integration
artificial
intelligence
is
proposed
as
a
promising
direction
achieve
smart
devices.
As
well
outlining
essential
characteristics
high-performance
wearable
skin
also
offer
insight
into
possible
future
applications.
Materials Chemistry Frontiers,
Journal Year:
2023,
Volume and Issue:
7(16), P. 3278 - 3297
Published: Jan. 1, 2023
A
flexible
sensor
is
a
key
part
of
intelligent
wearable
devices.
The
design
micro–nano
structured
materials
in
sensors
crucial.
Therefore,
the
recent
application
devices
summarized.
ACS Applied Materials & Interfaces,
Journal Year:
2023,
Volume and Issue:
15(24), P. 29486 - 29498
Published: June 9, 2023
The
increasing
prevalence
of
health
problems
stemming
from
sedentary
lifestyles
and
evolving
workplace
cultures
has
placed
a
substantial
burden
on
healthcare
systems.
Consequently,
remote
wearable
monitoring
systems
have
emerged
as
essential
tools
to
track
individuals'
well-being.
Self-powered
triboelectric
nanogenerators
(TENGs)
exhibited
significant
potential
for
use
emerging
detection
devices
capable
recognizing
body
movements
breathing
patterns.
However,
several
challenges
remain
be
addressed
in
order
fulfill
the
requirements
self-healing
ability,
air
permeability,
energy
harvesting,
suitable
sensing
materials.
These
materials
must
possess
high
flexibility,
lightweight,
excellent
charging
effects
both
electropositive
electronegative
layers.
In
this
work,
we
investigated
self-healable
electrospun
polybutadiene-based
urethane
(PBU)
positive
layer
titanium
carbide
(Ti3C2Tx)
MXene
negative
fabrication
an
energy-harvesting
TENG
device.
PBU
consists
maleimide
furfuryl
components
well
hydrogen
bonds
that
trigger
Diels–Alder
reaction,
contributing
its
properties.
Moreover,
incorporates
multitude
carbonyl
amine
groups,
which
create
dipole
moments
stiff
flexible
segments
polymer.
This
characteristic
positively
influences
qualities
by
facilitating
electron
transfer
between
contacting
materials,
ultimately
resulting
output
performance.
We
employed
device
applications
monitor
human
motion
pattern
recognition.
soft
fibrous-structured
generates
stable
open-circuit
voltage
up
30
V
short-circuit
current
4
μA
at
operation
frequency
4.0
Hz,
demonstrating
remarkable
cyclic
stability.
A
feature
our
is
allows
restoration
functionality
performance
after
sustaining
damage.
been
achieved
through
utilization
fibers,
can
repaired
via
simple
vapor
solvent
method.
innovative
approach
enables
maintain
optimal
continue
functioning
effectively
even
multiple
uses.
After
integration
with
rectifier,
charge
various
capacitors
power
120
LEDs.
self-powered
active
sensor,
attaching
it
purposes.
Additionally,
demonstrates
capability
recognize
patterns
real
time,
offering
valuable
insights
into
individual's
respiratory
health.
ACS Applied Materials & Interfaces,
Journal Year:
2023,
Volume and Issue:
15(5), P. 7380 - 7391
Published: Jan. 26, 2023
Flexible
strain
sensors
that
mimic
the
properties
of
human
skin
have
recently
attracted
tremendous
attention.
However,
integrating
multiple
functions
into
one
sensor,
e.g.,
stretchability,
full-range
motion
response,
and
self-healing
capability,
is
still
an
enormous
challenge.
Herein,
a
skin-like
sensor
was
presented
by
construction
hierarchically
structured
carbon
nanofibers
(CNFs),
followed
encapsulation
elastic
polyurethane
(PU).
The
hierarchical
sensing
structure
composed
diversified
CNFs
with
orientations
from
highly
aligned
to
randomly
oriented,
their
different
fracture
mechanisms
enabled
resultant
successfully
integrate
key
including
high
sensitivity
(gauge
factor
90),
wide
range
(∼80%
strain),
fast
response
(52
ms).
These
properties,
combined
stretchability
(870%)
excellent
stability
(>2000
cycles),
allowed
precisely
detect
motions
large
joint
subtle
physiological
signals.
Moreover,
had
spontaneous
capability
at
room
temperature
healing
efficiencies
97.7%,
while
process
could
substantially
be
accelerated
natural
sunlight
(24
h
→
0.5
h).
healed
possessed
comparable
performance,
accurate
monitoring
ability
body
signals
original
sensor.
biomimetic
functionality
along
makes
it
attractive
for
next-generation
wearable
electronics.
