Advanced Materials Technologies,
Journal Year:
2025,
Volume and Issue:
unknown
Published: April 24, 2025
Abstract
3D
bioprinting
has
emerged
as
a
transformative
technology
in
tissue
engineering,
significantly
impacting
the
creation
of
patient‐specific
tissues
to
enhance
clinical
outcomes.
Despite
its
rapid
advancement,
translating
this
from
bench
bedside
remains
critical
need.
New
approaches,
such
handheld
printers
or
robotic
arm‐driven
situ
biofabrication
techniques,
have
promising
alternatives.
These
advancements
enable
reconstruction
damaged
directly
on
living
anatomical
structures,
offering
adaptability
and
precise
matching
affected
area.
The
integration
biomaterials,
engineering
principles,
digital
technologies,
particularly
robotics,
garnered
substantial
interest
both
academic
industrial
sectors,
highlighting
potential
for
applications.
However,
challenges
persist,
including
refining
bioink
formulations,
adjusting
mechanical
properties,
facilitating
crosslinking,
accurately
mimicking
extracellular
matrix.
This
review
explores
cutting‐edge
frontier
regeneration,
utilizing
arm‐assisted
printers.
It
systematically
examines
relative
advantages,
disadvantages,
challenges,
prospects
it
transitions
side
bed
side.
International Journal of Extreme Manufacturing,
Journal Year:
2023,
Volume and Issue:
5(3), P. 032004 - 032004
Published: May 31, 2023
Abstract
Articular
cartilage
damage
caused
by
trauma
or
degenerative
pathologies
such
as
osteoarthritis
can
result
in
significant
pain,
mobility
issues,
and
disability.
Current
surgical
treatments
have
a
limited
capacity
for
efficacious
repair,
long-term
patient
outcomes
are
not
satisfying.
Three-dimensional
bioprinting
has
been
used
to
fabricate
biochemical
biophysical
environments
that
aim
recapitulate
the
native
microenvironment
promote
tissue
regeneration.
However,
conventional
vitro
limitations
due
challenges
associated
with
fabrication
implantation
of
bioprinted
constructs
their
integration
tissue.
In
situ
is
novel
strategy
directly
deliver
bioinks
desired
anatomical
site
potential
overcome
major
shortcomings
bioprinting.
this
review,
we
focus
on
new
frontier
robotic-assisted
systems
We
outline
existing
clinical
approaches
utilization
systems.
Handheld
techniques
including
minimally
invasive
non-invasive
defined
presented.
Finally,
discuss
future
perspectives
applications.
Advanced Intelligent Systems,
Journal Year:
2024,
Volume and Issue:
unknown
Published: Sept. 9, 2024
One
of
the
practical
applications
in
field
soft
robotics
involves
development
robotic
wearable
devices.
These
devices
make
use
their
intrinsically
compliant
structures
to
interact
safely
and
harmoniously
with
human
body.
While
robots
demonstrate
utility
lower‐limb
for
locomotion,
upper‐limb
domain
offers
significant
prospects
a
wide
range
that
technology
can
address.
In
this
review,
current
state
upper
limbs
is
systematically
analyzed
categorized.
Categorizations
are
made
based
on
rehabilitation,
activities
daily
living
support,
augmentation.
Furthermore,
study,
also
contemporary
technological
aspects,
encompassing
sensing
control
systems,
explored.
Despite
exciting
potential
domain,
several
limitations
from
existing
inherently
impede
widespread
adoption
thus
hinder
further
progress
field.
an
overview
different
facets
provided
key
considerations
advancement
intended
prescribed.
Advanced Materials Technologies,
Journal Year:
2025,
Volume and Issue:
unknown
Published: April 24, 2025
Abstract
3D
bioprinting
has
emerged
as
a
transformative
technology
in
tissue
engineering,
significantly
impacting
the
creation
of
patient‐specific
tissues
to
enhance
clinical
outcomes.
Despite
its
rapid
advancement,
translating
this
from
bench
bedside
remains
critical
need.
New
approaches,
such
handheld
printers
or
robotic
arm‐driven
situ
biofabrication
techniques,
have
promising
alternatives.
These
advancements
enable
reconstruction
damaged
directly
on
living
anatomical
structures,
offering
adaptability
and
precise
matching
affected
area.
The
integration
biomaterials,
engineering
principles,
digital
technologies,
particularly
robotics,
garnered
substantial
interest
both
academic
industrial
sectors,
highlighting
potential
for
applications.
However,
challenges
persist,
including
refining
bioink
formulations,
adjusting
mechanical
properties,
facilitating
crosslinking,
accurately
mimicking
extracellular
matrix.
This
review
explores
cutting‐edge
frontier
regeneration,
utilizing
arm‐assisted
printers.
It
systematically
examines
relative
advantages,
disadvantages,
challenges,
prospects
it
transitions
side
bed
side.
