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.
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.
Lab on a Chip,
Journal Year:
2024,
Volume and Issue:
24(4), P. 832 - 842
Published: Jan. 1, 2024
A
high-performance
pure-nickel
magnetically-actuated
microrobot
(Ni-MAR)
is
printed
by
a
‘femtosecond
laser
polymerization
+
sintering’
method
with
great
potential
applications
in
controlled
locomotion
fast-flowing
blood
and
massive
drugs
delivery.
Journal of Materials Chemistry B,
Journal Year:
2024,
Volume and Issue:
12(19), P. 4584 - 4612
Published: Jan. 1, 2024
Recent
advancements
pertaining
to
the
application
of
3D,
4D,
5D,
and
6D
bioprinting
in
cancer
research
are
discussed,
focusing
on
important
challenges
future
perspectives.
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.
