Virtual and Physical Prototyping,
Journal Year:
2024,
Volume and Issue:
19(1)
Published: Nov. 4, 2024
3D
bioprinting
is
at
the
forefront
of
tissue
engineering
to
fabricate
complex
constructs
resembling
functional
tissues.
However,
inability
produce
heterogeneous
tissues
and
lack
spatio-temporal
control
over
release
bioactive
factors
are
greatly
limiting
clinical
translation.
Herein,
combination
with
high-throughput
dispensing
using
a
custom
microfluidic
system
nanoclay-based
inks
presented.
This
approach
was
found
enhance
printability,
retention,
controlled
factors.
Advanced
models
were
developed
resemble
cancer
skeletal
tissue,
while
studying
effect
anti-cancer
(Doxorubicin)
pro-osteogenic
growth
(bone
morphogenetic
protein-2,
BMP-2),
respectively.
The
new
nanoclay
ink
allowed
sustained
release,
making
it
suitable
for
long-term
applications.
These
findings
suggest
that
by
combining
delivery
platform
can
be
assembled,
offering
significant
advancements
in
regenerative
medicine.
Chemical Society Reviews,
Journal Year:
2024,
Volume and Issue:
53(8), P. 4086 - 4153
Published: Jan. 1, 2024
This
review
critically
analyzes
degradable
biomedical
elastomers,
focusing
on
their
degradation,
synthesis,
microstructure,
and
role
in
tissue
repair.
It
guides
experts
balancing
degradation
with
repair
for
improved
applications.
Materials & Design,
Journal Year:
2024,
Volume and Issue:
240, P. 112853 - 112853
Published: March 19, 2024
3D
bioprinting
techniques
have
emerged
as
a
flexible
tool
in
tissue
engineering
and
regenerative
medicine
to
fabricate
or
pattern
functional
bio-structures
with
precise
geometric
designs,
bridging
the
divergence
between
engineered
natural
constructs.
A
significantly
increasing
development
has
been
achieved
understanding
relationship
3D-printing
process
structures,
properties,
applications
of
objects
created.
The
ongoing
advancement
novel
biomaterial
inks
enabled
manufacturing
models
vitro
implants
capable
achieving
some
level
success
preclinical
trials.
Remarkable
progress
cell
biology
biology-inspired
computational
design
assisted
latest
milestone
planned
tissue-
organ-like
constructs
having
specific
levels
functionality.
However,
biofabricated
still
long
way
go
before
reaching
clinics.
This
review
presents
picture
context
medicine,
focus
on
biomaterials-related
design-centred
aspects.
Biomedical
are
described
detail
relation
major
tissues
organs
considered
human
body.
Current
technical
limitations,
challenges,
future
prospects
improvements
critically
outlined
discussed.
Chemical Reviews,
Journal Year:
2024,
Volume and Issue:
124(3), P. 1247 - 1287
Published: Jan. 23, 2024
Metallic
materials
are
usually
composed
of
single
phase
or
multiple
phases,
which
refers
to
homogeneous
regions
with
distinct
types
the
atom
arrangement.
The
recent
studies
on
nanostructured
metallic
provide
a
variety
promising
approaches
engineer
phases
at
nanoscale.
Tailoring
size,
distribution,
and
introducing
new
structures
via
transformation
contribute
precise
modification
in
deformation
behaviors
electronic
nanostructural
materials.
Therefore,
engineering
is
expected
pave
an
innovative
way
develop
advanced
mechanical
functional
properties.
In
this
review,
we
present
comprehensive
overview
heterogeneous
nanophases
fundamental
understanding
nanophase
formation
for
materials,
including
supra-nano-dual-phase
nanoprecipitation-
nanotwin-strengthened
We
first
review
thermodynamics
kinetics
principles
structure,
followed
by
discussion
mechanism
structural
as
well
optimization
structure
electrocatalysis.
Then,
demonstrate
origin,
classification,
properties
characteristics
dense
nanoprecipitations
nanotwins.
Finally,
summarize
some
potential
research
challenges
field
short
perspective
scientific
implications
design
next-generation
Bioactive Materials,
Journal Year:
2024,
Volume and Issue:
37, P. 348 - 377
Published: April 23, 2024
Setting
time
as
the
fourth
dimension,
4D
printing
allows
us
to
construct
dynamic
structures
that
can
change
their
shape,
property,
or
functionality
over
under
stimuli,
leading
a
wave
of
innovations
in
various
fields.
Recently,
smart
biomaterials,
biological
components,
and
living
cells
into
3D
constructs
with
effects
has
led
an
exciting
field
bioprinting.
bioprinting
gained
increasing
attention
is
being
applied
create
programmed
cell-laden
such
bone,
cartilage,
vasculature.
This
review
presents
overview
on
for
engineering
tissues
organs,
followed
by
discussion
approaches,
technologies,
biomaterials
design,
bioink
requirements,
applications.
While
much
progress
been
achieved,
complex
process
facing
challenges
need
be
addressed
transdisciplinary
strategies
unleash
full
potential
this
advanced
biofabrication
technology.
Finally,
we
present
future
perspectives
rapidly
evolving
bioprinting,
view
its
potential,
increasingly
important
roles
development
basic
research,
pharmaceutics,
regenerative
medicine.
Nanomaterials,
Journal Year:
2024,
Volume and Issue:
14(6), P. 531 - 531
Published: March 16, 2024
Biomimetic
scaffolds
imitate
native
tissue
and
can
take
a
multidimensional
form.
They
are
biocompatible
influence
cellular
metabolism,
making
them
attractive
bioengineering
platforms.
The
use
of
biomimetic
adds
complexity
to
traditional
cell
cultivation
methods.
most
commonly
used
technique
involves
cultivating
cells
on
flat
surface
in
two-dimensional
format
due
its
simplicity.
A
three-dimensional
(3D)
provide
microenvironment
for
surrounding
cells.
There
two
main
techniques
obtaining
3D
structures
based
the
presence
scaffolding.
Scaffold-free
consist
spheroid
technologies.
Meanwhile,
scaffold
contain
organoids
all
constructs
that
various
types
scaffolds,
ranging
from
decellularized
extracellular
matrix
(dECM)
through
hydrogels
one
extensively
studied
forms
potential
culture
up
4D
bioprinted
biomaterials.
bioprinting
is
important
create
scaffolds.
versatility
this
allows
many
different
inks,
mainly
hydrogels,
as
well
inorganic
substances.
Increasing
amounts
data
evidence
vast
usage
engineering
personalized
medicine,
with
area
application
being
regeneration
skin
musculoskeletal
systems.
Recent
papers
also
indicate
increasing
vivo
tests
products
which
further
strengthen
importance
branch
emphasize
need
extensive
research
safe
humansbiomimetic
tissues
organs.
In
review
article,
we
recent
advancements
field
preceded
by
an
overview
technologies
led
development
complex
type
culture.
Macromolecular Materials and Engineering,
Journal Year:
2025,
Volume and Issue:
unknown
Published: Jan. 14, 2025
Abstract
4D
bioprinting
is
a
groundbreaking
technology
with
potential
to
revolutionize
healthcare.
It
based
on
additive
manufacturing
technologies,
which
are
used
fabricate
dynamic
prosthetics
and
devices
from
biologically
compatible
smart
materials
that
respond
stimuli.
The
ultimate
end
of
the
creation
an
artificial
organ
perfectly
mimics
functional
movements
native
fully
integrated
within
human
body.
In
this
perspective,
two
phases
identified
toward
end.
first
minimally
invasive
surgery
(MIS)
using
shape
memory
composites
stimulated
by
near‐infrared
(NIR)
light
and/or
magnetic
fields.
second
tissue
engineering
(DTE)
activation
biological
Materials Horizons,
Journal Year:
2023,
Volume and Issue:
11(3), P. 590 - 625
Published: Nov. 10, 2023
In
order
to
address
the
issue
of
bacterial
infection
during
transplantation
bone
implants,
four
types
implants
with
long-term
antimicrobial
functionality
have
been
constructed.
Macromolecular Rapid Communications,
Journal Year:
2024,
Volume and Issue:
45(7)
Published: Jan. 25, 2024
Photocuring
3D
printing
of
hydrogels,
with
sophisticated,
delicate
structures
and
biocompatibility,
attracts
significant
attention
by
researchers
possesses
promising
application
in
the
fields
tissue
engineering
flexible
devices.
After
years
development,
photocuring
technologies
hydrogel
inks
make
great
progress.
Herein,
techniques
including
direct
ink
writing
(DIW),
stereolithography
(SLA),
digital
light
processing
(DLP),
continuous
liquid
interface
production
(CLIP),
volumetric
additive
manufacturing
(VAM),
two
photon
polymerization
(TPP)
are
reviewed.
Further,
raw
materials
for
(photocurable
polymers,
monomers,
photoinitiators,
additives)
applications
devices
also
At
last,
current
challenges
future
perspectives
hydrogels
discussed.
