Bioengineering,
Journal Year:
2023,
Volume and Issue:
10(12), P. 1373 - 1373
Published: Nov. 29, 2023
In
the
early
years
of
tissue
engineering,
scientists
focused
on
generation
healthy-like
tissues
and
organs
to
replace
diseased
areas
with
aim
filling
gap
between
organ
demands
actual
donations.
Over
time,
realization
has
set
in
that
there
is
an
additional
large
unmet
need
for
suitable
disease
models
study
their
progression
test
refine
different
treatment
approaches.
Increasingly,
researchers
have
turned
engineering
address
this
controllable
translational
models.
We
review
existing
potential
uses
tissue-engineered
cardiovascular
research
suggest
guidelines
generating
adequate
models,
aimed
both
at
studying
mechanisms
supporting
development
dedicated
drug-delivery
therapies.
This
involves
discussion
requirements
drugs,
nanoparticles,
drug-eluting
devices.
addition
realistic
cellular
composition,
mechanical
structural
properties
are
needed
simulate
pathological
reality
addressed.
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.
Applied Physics Reviews,
Journal Year:
2025,
Volume and Issue:
12(1)
Published: March 1, 2025
Smart
biomaterials
have
significantly
impacted
human
healthcare
by
advancing
the
development
of
medical
devices
designed
to
function
within
tissue,
mimicking
behavior
natural
tissues.
While
intelligence
has
evolved
from
inert
active
over
past
few
decades,
smart
take
this
a
step
further
making
their
surfaces
or
bulk
respond
based
on
interactions
with
surrounding
tissues,
imparting
outcomes
similar
tissue
functions.
This
interaction
helps
in
creating
stimuli-responsive
biomaterials,
which
can
be
useful
engineering,
regenerative
medicine,
autonomous
drug
delivery,
orthopedics,
and
much
more.
Traditionally,
material
engineering
focused
refining
static
properties
accommodate
them
body
without
evoking
an
immune
response,
was
major
obstacle
unrestricted
operation.
review
highlights
explains
various
approaches
currently
under
research
for
developing
that
tune
responses
bodily
factors
like
temperature,
pH,
ion
concentration
external
magnetism,
light,
conductivity.
Applications
soft
hard
4D
printing,
scaffold
design
are
also
discussed.
The
advanced
application
microfluidics,
organ-on-a-chip
models,
extensively
benefits
intrinsic
discussed
below.
elaborates
how
biomaterial
could
revolutionize
biosensor
applications,
thereby
improving
patient
care
quality.
We
delineate
limitations
key
challenges
associated
providing
insights
into
path
forward
outlining
future
directions
next-generation
will
facilitate
clinical
translation.
European Journal of Pharmaceutical Sciences,
Journal Year:
2024,
Volume and Issue:
196, P. 106761 - 106761
Published: April 3, 2024
Inspired
by
nature,
tissue
engineering
aims
to
employ
intricate
mechanisms
for
advanced
clinical
interventions,
unlocking
inherent
biological
potential
and
propelling
medical
breakthroughs.
Therefore,
medical,
pharmaceutical
fields
are
growing
interest
in
organ
replacement,
repair,
regeneration
this
technology.
Three
primary
currently
used
engineering:
transplantation
of
cells
(I),
injection
growth
factors
(II)
cellular
seeding
scaffolds
(III).
However,
develop
presenting
highest
potential,
reinforcement
with
polymeric
materials
is
interest.
For
instance,
natural
synthetic
polymers
can
be
used.
Regardless,
chitosan
keratin
two
biopolymers
great
biocompatibility,
biodegradability
non-antigenic
properties
purposes
offering
restoration
revitalization.
combination
has
been
studied
results
exhibit
highly
porous
providing
optimal
environment
cultivation.
This
review
give
an
historical
as
well
current
overview
engineering,
involved
the
field.
Polymers,
Journal Year:
2024,
Volume and Issue:
16(13), P. 1878 - 1878
Published: July 1, 2024
Heart
problems
are
quite
prevalent
worldwide.
Cardiomyocytes
and
stem
cells
two
examples
of
the
supporting
matrix
that
used
in
integrated
process
cardiac
tissue
regeneration.
The
objective
is
to
create
innovative
materials
can
effectively
replace
or
repair
damaged
muscle.
One
most
effective
appealing
3D/4D
scaffolds
for
creating
an
appropriate
milieu
growth
healing
hydrogel.
In
order
successfully
regenerate
heart
tissue,
bioactive
biocompatible
hydrogels
required
preserve
infarcted
region
bid
support
restoration
myocardial
wall
stress,
cell
survival
function.
engineering
uses
a
variety
hydrogels,
such
as
natural
synthetic
polymeric
hydrogels.
This
article
provides
quick
overview
various
hydrogel
types
employed
engineering.
Their
benefits
drawbacks
discussed.
Hydrogel-based
techniques
regeneration
also
addressed,
along
with
their
clinical
application
future
Cellular Oncology,
Journal Year:
2024,
Volume and Issue:
47(4), P. 1113 - 1126
Published: March 23, 2024
Cancer
immunotherapy
is
receiving
worldwide
attention
for
its
induction
of
an
anti-tumor
response.
However,
it
has
had
limited
efficacy
in
some
patients
who
acquired
resistance.
The
dynamic
and
sophisticated
complexity
the
tumor
microenvironment
(TME)
leading
contributor
to
this
clinical
dilemma.
Through
recapitulating
physiological
features
TME,
3D
bioprinting
a
promising
research
tool
cancer
immunotherapy,
which
preserves
vivo
malignant
aggressiveness,
heterogeneity,
cell-cell/matrix
interactions.
It
been
reported
that
application
holds
potential
address
challenges
resistance
facilitate
personalized
medication.
Tissue Engineering Part A,
Journal Year:
2024,
Volume and Issue:
30(13-14), P. 387 - 408
Published: Jan. 11, 2024
Bioprinting
describes
the
printing
of
biomaterials
and
cell-laden
or
cell-free
hydrogels
with
various
combinations
embedded
bioactive
molecules.
It
encompasses
precise
patterning
cells
to
create
scaffolds
for
different
biomedical
needs.
There
are
many
requirements
that
bioprinting
face,
it
is
ultimately
interplay
between
scaffold's
structure,
properties,
processing,
performance
will
lead
its
successful
translation.
Among
essential
properties
must
possess—adequate
appropriate
application-specific
chemical,
mechanical,
biological
performance—the
mechanical
behavior
hydrogel-based
bioprinted
key
their
stable
in
vivo
at
site
implantation.
Hydrogels
typically
constitute
main
scaffold
material
medium
biomolecules
very
soft,
often
lack
sufficient
stability,
which
reduces
printability
and,
therefore,
potential.
The
aim
this
review
article
highlight
reinforcement
strategies
used
approaches
achieve
enhanced
stability
bioinks
printed
scaffolds.
Enabling
robust
materials
processes
creation
truly
complex
remarkable
structures
could
accelerate
application
smart,
functional
settings.
a
powerful
tool
fabrication
3D
applications.
has
gained
tremendous
attention
recent
years,
bioink
library
expanding
include
more
combinations.
From
practical
perspective,
need
be
considered,
such
as
structure's
performances.
these,
constructs
critical
translation
into
clinic.
explore
stabilization
structures.
Journal of Cardiovascular Development and Disease,
Journal Year:
2024,
Volume and Issue:
11(1), P. 22 - 22
Published: Jan. 12, 2024
Cardiovascular
CT
is
being
widely
used
in
the
diagnosis
of
cardiovascular
disease
due
to
rapid
technological
advancements
scanning
techniques.
These
include
development
multi-slice
CT,
from
early
generation
latest
models,
which
has
capability
acquiring
images
with
high
spatial
and
temporal
resolution.
The
recent
emergence
photon-counting
further
enhanced
performance
clinical
applications,
providing
improved
contrast
CT-derived
fractional
flow
reserve
superior
standard
CT-based
anatomical
assessment
for
detection
lesion-specific
myocardial
ischemia.
3D-printed
patient-specific
models
are
also
offering
advantages
terms
educational
value,
surgical
planning,
simulation
treatment,
as
well
enhancing
doctor-patient
communication.
Three-dimensional
visualization
tools
including
virtual
reality,
augmented
mixed
reality
advancing
value
disease.
With
widespread
use
artificial
intelligence,
machine
learning,
deep
learning
disease,
diagnostic
significantly
improved,
promising
results
presented
both
prediction.
This
review
article
provides
an
overview
applications
covering
its
perspective
based
on
traditional
lumen
identification
vulnerable
lesions
prediction
outcomes
these
advanced
technologies.
limitations
future
prospects
technologies
discussed.
