Deleted Journal,
Journal Year:
2024,
Volume and Issue:
3, P. 520 - 520
Published: Dec. 31, 2024
The
creation
of
mechanical
devices
driven
by
artificial
intelligence
(AI)
is
a
huge
step
forward
in
rehabilitative
medicine.
These
will
make
it
easier
for
people
who
have
lost
limbs
to
move
around
and
give
them
real-time
brain
control.
This
study
paper
looks
into
how
AI
technologies
can
be
used
the
user
experience
smooth
natural.
Machine
learning
techniques
are
at
heart
our
method
because
they
read
neural
data
straight
from
user's
nervous
system.
lets
device
react
real
time
free
muscle
movements.
mostly
about
making
connections
that
pick
up
electrophysiological
signals.
signals
then
handled
advanced
models
figure
out
what
movements
meant
happen.
After
that,
arms
these
moves
with
level
accuracy
response
very
close
work.
We
also
talk
feedback
loops
let
get
sense
information
device,
which
improves
their
ability
feel
touch
body
space.
Our
uses
diverse
approach
combines
robots,
neuroscience,
biotech.
key
connects
fields
system
works
well
together.
Preliminary
tests
shown
speed
control
gotten
lot
better,
much
on
users'
bodies
minds.
Also,
patient
shows
more
comfortable
easy
use,
suggests
has
higher
chance
being
adopted.
not
only
pushes
limits
medical
engineering,
but
promise
helping
amputees
regain
freedom
quality
life.
Gels,
Journal Year:
2024,
Volume and Issue:
10(4), P. 216 - 216
Published: March 22, 2024
Hydrogels,
being
hydrophilic
polymer
networks
capable
of
absorbing
and
retaining
aqueous
fluids,
hold
significant
promise
in
biomedical
applications
owing
to
their
high
water
content,
permeability,
structural
similarity
the
extracellular
matrix.
Recent
chemical
advancements
have
bolstered
versatility,
facilitating
integration
molecules
guiding
cellular
activities
enabling
controlled
activation
under
time
constraints.
However,
conventional
synthetic
hydrogels
suffer
from
inherent
weaknesses
such
as
heterogeneity
network
imperfections,
which
adversely
affect
mechanical
properties,
diffusion
rates,
biological
activity.
In
response
these
challenges,
hybrid
emerged,
aiming
enhance
strength,
drug
release
efficiency,
therapeutic
effectiveness.
These
hydrogels,
featuring
improved
formulations,
are
tailored
for
tissue
regeneration
across
both
soft
hard
tissues.
The
scientific
community
has
increasingly
recognized
versatile
characteristics
particularly
sector.
This
comprehensive
review
delves
into
recent
hydrogel
systems,
covering
diverse
types,
modification
strategies,
nano/microstructures.
discussion
includes
innovative
fabrication
techniques
click
reactions,
3D
printing,
photopatterning
alongside
elucidation
mechanisms
bioactive
molecules.
By
addressing
underscores
envisages
a
promising
future
various
domains
field.
Chemical Engineering Journal,
Journal Year:
2024,
Volume and Issue:
493, P. 152445 - 152445
Published: May 21, 2024
With
the
increasing
demand
for
tissue
adhesive,
soft
self-healing,
antifouling,
biodegradable
and
biocompatible
biosensors,
use
of
biomimetic
polymers
has
paved
way
development
these
advanced
sensing
systems.
Especially,
have
provided
new
opportunities
directions
implantable
wearable
biosensors.
In
fact,
impressive
in
bio-inspired
composites
based
on
led
to
creation
tissue-adhesive
biosensors
with
minimal
immune
response
or
biofouling.
This
review
aims
cover
advances
mimetic
(natural
synthetic)
an
emphasis
state-of-the-art
devices
composites.
It
also
highlights
unique
properties
such
as
self-adhesion,
enzyme-like
activity,
antibacterial
regenerative
etc.
Considering
high
rate
cancer
world,
especially
developing
countries,
a
separate
section
is
dedicated
biopolymers-based
sensors
early
diagnosis
cancer.
Finally,
outlook
current
challenges
future
developments
this
field
presented.
Biomimetics,
Journal Year:
2024,
Volume and Issue:
9(5), P. 273 - 273
Published: April 30, 2024
Recent
advancements
in
biomimetics
have
spurred
significant
innovations
prosthetic
limb
development
by
leveraging
the
intricate
designs
and
mechanisms
found
nature.
Biomimetics,
also
known
as
“nature-inspired
engineering”,
involves
studying
emulating
biological
systems
to
address
complex
human
challenges.
This
comprehensive
review
provides
insights
into
latest
trends
biomimetic
prosthetics,
focusing
on
knowledge
from
natural
biomechanics,
sensory
feedback
mechanisms,
control
closely
mimic
appendages.
Highlighted
breakthroughs
include
integration
of
cutting-edge
materials
manufacturing
techniques
such
3D
printing,
facilitating
seamless
anatomical
limbs.
Additionally,
incorporation
neural
interfaces
enhances
movement,
while
technologies
like
scanning
enable
personalized
customization,
optimizing
comfort
functionality
for
individual
users.
Ongoing
research
efforts
hold
promise
further
advancements,
offering
enhanced
mobility
individuals
with
loss
or
impairment.
illuminates
dynamic
landscape
technology,
emphasizing
its
transformative
potential
rehabilitation
assistive
technologies.
It
envisions
a
future
where
solutions
seamlessly
integrate
body,
augmenting
both
quality
life.
Neurorehabilitation and neural repair,
Journal Year:
2025,
Volume and Issue:
unknown
Published: April 24, 2025
Background
and
Objectives
Prosthetic
hand
development
is
undergoing
a
transformative
phase,
blending
biomimicry
neural
interface
technologies
to
redefine
functionality
sensory
feedback.
This
article
explores
the
symbiotic
relationship
between
biomimetic
design
principles
technology
(NIT)
in
advancing
prosthetic
capabilities.
Methods
Drawing
inspiration
from
biological
systems,
researchers
aim
replicate
intricate
movements
capabilities
of
human
through
innovative
designs.
Central
this
endeavor
NIT,
facilitating
seamless
communication
artificial
devices
nervous
system.
Recent
advances
fabrication
methods
have
propelled
brain–computer
interfaces,
enabling
precise
control
hands
by
decoding
activity.
Results
Anatomical
complexities
underscore
importance
understanding
biomechanics,
neuroanatomy,
mechanisms
for
crafting
effective
solutions.
Furthermore,
achieving
goal
fully
functional
cyborg
necessitates
multidisciplinary
approach
body’s
inherent
By
incorporating
expertise
clinicians,
tissue
engineers,
bioengineers,
electronic
data
scientists,
next
generation
implantable
not
only
anatomically
biomechanically
accurate
but
also
offer
intuitive
control,
feedback,
proprioception,
thereby
pushing
boundaries
current
technology.
Conclusion
integrating
machine
learning
algorithms,
biomechatronic
principles,
advanced
surgical
techniques,
can
achieve
real-time
while
restoring
tactile
sensation
proprioception.
manuscript
contributes
novel
approaches
development,
with
potential
implications
enhancing
functionality,
durability,
safety
limb.
