Chemical Reviews,
Journal Year:
2024,
Volume and Issue:
124(2), P. 455 - 553
Published: Jan. 4, 2024
In
the
era
of
Internet-of-things,
many
things
can
stay
connected;
however,
biological
systems,
including
those
necessary
for
human
health,
remain
unable
to
connected
global
Internet
due
lack
soft
conformal
biosensors.
The
fundamental
challenge
lies
in
fact
that
electronics
and
biology
are
distinct
incompatible,
as
they
based
on
different
materials
via
functioning
principles.
particular,
body
is
curvilinear,
yet
typically
rigid
planar.
Recent
advances
design
have
generated
tremendous
opportunities
wearable
bioelectronics,
which
may
bridge
gap,
enabling
ultimate
dream
healthcare
anyone,
anytime,
anywhere.
We
begin
with
a
review
historical
development
healthcare,
indicating
significant
trend
healthcare.
This
followed
by
focal
point
discussion
about
new
design,
particularly
low-dimensional
nanomaterials.
summarize
material
types
their
attributes
designing
bioelectronic
sensors;
we
also
cover
synthesis
fabrication
methods,
top-down,
bottom-up,
combined
approaches.
Next,
discuss
energy
challenges
progress
made
date.
addition
front-end
devices,
describe
back-end
machine
learning
algorithms,
artificial
intelligence,
telecommunication,
software.
Afterward,
integration
systems
been
applied
various
testbeds
real-world
settings,
laboratories
preclinical
clinical
environments.
Finally,
narrate
remaining
conjunction
our
perspectives.
Advanced Functional Materials,
Journal Year:
2021,
Volume and Issue:
32(17)
Published: Dec. 26, 2021
Chronic
wounds
are
a
major
healthcare
issue
and
can
adversely
affect
the
lives
of
millions
patients
around
world.
The
current
wound
management
strategies
have
limited
clinical
efficacy
due
to
labor-intensive
lab
analysis
requirements,
need
for
clinicians'
experiences,
long-term
frequent
interventions,
limiting
therapeutic
efficiency
applicability.
growing
field
flexible
bioelectronics
enables
great
potential
personalized
care
owing
its
advantages
such
as
wearability,
low-cost,
rapid
simple
application.
Herein,
recent
advances
in
development
wearable
monitoring
chronic
comprehensively
reviewed.
First,
design
principles
key
features
that
adapt
unique
milieu
introduced.
Next,
state
biosensors
on-demand
systems
summarized
highlighted.
Furthermore,
we
discuss
criteria
integrated
closed
loop
devices.
Finally,
future
perspectives
challenges
discussed.
Biosensors,
Journal Year:
2021,
Volume and Issue:
11(8), P. 245 - 245
Published: July 23, 2021
Recent
advances
in
microfluidics,
microelectronics,
and
electrochemical
sensing
methods
have
steered
the
way
for
development
of
novel
potential
wearable
biosensors
healthcare
monitoring.
Wearable
bioelectronics
has
received
tremendous
attention
worldwide
due
to
its
great
a
predictive
medical
modeling
allowing
personalized
point-of-care-testing
(POCT).
They
possess
many
appealing
characteristics,
example,
lightweight,
flexibility,
good
stretchability,
conformability,
low
cost.
These
characteristics
make
promising
platform
devices.
In
this
paper,
we
review
recent
progress
flexible
sensors
non-invasive
biomonitoring
using
sweat
as
bio-fluid.
Real-time
molecular-level
monitoring
personal
health
states
can
be
achieved
with
sweat-based
or
perspiration-based
biosensors.
The
suitability
monitoring,
extraction,
challenges
encountered
analysis
are
summarized.
paper
also
discusses
that
still
hinder
full-fledged
wearables
presents
areas
future
research.
Chemical Reviews,
Journal Year:
2024,
Volume and Issue:
124(2), P. 455 - 553
Published: Jan. 4, 2024
In
the
era
of
Internet-of-things,
many
things
can
stay
connected;
however,
biological
systems,
including
those
necessary
for
human
health,
remain
unable
to
connected
global
Internet
due
lack
soft
conformal
biosensors.
The
fundamental
challenge
lies
in
fact
that
electronics
and
biology
are
distinct
incompatible,
as
they
based
on
different
materials
via
functioning
principles.
particular,
body
is
curvilinear,
yet
typically
rigid
planar.
Recent
advances
design
have
generated
tremendous
opportunities
wearable
bioelectronics,
which
may
bridge
gap,
enabling
ultimate
dream
healthcare
anyone,
anytime,
anywhere.
We
begin
with
a
review
historical
development
healthcare,
indicating
significant
trend
healthcare.
This
followed
by
focal
point
discussion
about
new
design,
particularly
low-dimensional
nanomaterials.
summarize
material
types
their
attributes
designing
bioelectronic
sensors;
we
also
cover
synthesis
fabrication
methods,
top-down,
bottom-up,
combined
approaches.
Next,
discuss
energy
challenges
progress
made
date.
addition
front-end
devices,
describe
back-end
machine
learning
algorithms,
artificial
intelligence,
telecommunication,
software.
Afterward,
integration
systems
been
applied
various
testbeds
real-world
settings,
laboratories
preclinical
clinical
environments.
Finally,
narrate
remaining
conjunction
our
perspectives.
