Polymers for Advanced Technologies,
Journal Year:
2025,
Volume and Issue:
36(4)
Published: March 31, 2025
ABSTRACT
3D
printing
technology
has
shown
significant
promise
in
bone
tissue
engineering,
enabling
the
fabrication
of
intricate
structures
while
controlling
porosity
and
mechanical
properties.
Integrating
into
provides
a
vital
benefit
by
allowing
implants
to
precisely
match
an
individual's
anatomy,
improving
outcomes
reducing
risk
rejection.
Additionally,
this
approach
supports
inclusion
bioactive
substances
growth
factors
enhance
regeneration.
This
study
examines
most
recent
advances
for
production,
stressing
their
potential
regenerative
medicine
personalized
healthcare.
It
also
addresses
challenges
associated
with
current
processes
engineering
explores
possible
avenues
future
research
development.
Furthermore,
article
investigates
how
biocompatibility
bioactivity
materials
used
facilitate
effective
Likewise,
it
evaluates
scaffold
design
architecture
can
promote
cell
attachment,
proliferation,
differentiation,
thereby
encouraging
successful
restoration.
In
conclusion,
thorough
assessment
offers
critical
insights
progress
obstacles
proposes
directions
inquiry
exciting
field.
By
leveraging
these
advancements,
clinicians
researchers
pioneer
new
therapies
that
address
defects
improve
outcomes.
Advanced Science,
Journal Year:
2025,
Volume and Issue:
unknown
Published: Feb. 27, 2025
Tissue
engineering
aims
to
repair
damaged
tissues
with
physiological
functions
recovery.
Although
several
therapeutic
strategies
are
there
for
tissue
regeneration,
the
functional
recovery
of
regenerated
still
poses
significant
challenges
due
lack
concerns
innervation.
Design
rationale
multifunctional
biomaterials
both
tissue-induction
and
neural
induction
activities
shows
great
potential
regeneration.
Recently,
research
application
inorganic
attracts
increasing
attention
in
innervated
multi-tissue
such
as
central
nerves,
bone,
skin,
because
its
superior
tunable
chemical
composition,
topographical
structures,
physiochemical
properties.
More
importantly,
easily
combined
other
organic
materials,
biological
factors,
external
stimuli
enhance
their
effects.
This
review
presents
a
comprehensive
overview
recent
advancements
It
begins
introducing
classification
properties
typical
design
inorganic-based
material
composites.
Then,
progresses
regenerating
various
nerves
nerve-innervated
systematically
reviewed.
Finally,
existing
future
perspectives
proposed.
may
pave
way
direction
offers
new
strategy
regeneration
combination
Polymer Bulletin,
Journal Year:
2024,
Volume and Issue:
81(10), P. 8595 - 8605
Published: Feb. 3, 2024
Abstract
Bone
fracture
healing
is
a
challenging
process,
due
to
insufficient
and
slow
tissue
repair.
Sufferers
from
bone
fractures
struggle
with
one-third
of
nonunion,
display
graft
rejection,
high-costed
implantation,
or
chronic
pain.
Novel
advances
in
engineering
presented
promising
options
for
this
strain.
Biomaterials
repair
allow
accelerated
regeneration,
osteoblastic
cell
activation,
enhanced
remodeling.
There
wide
range
biomaterials
that
are
biocompatible,
bioresorbable,
biodegradable
used
promoting
osteoconductive
osteoinductive
properties.
The
main
aim
generate
rapid
optimal
functional
regeneration
through
combination
biomaterials,
growth
factors,
cells,
various
agents.
Recently
has
been
attracted
the
use
bioactive
glass
scaffolds
incorporated
polymers
patient-specific
fabrication
material
by
3D
bioprinting.
future
outcomes
were
reported
several
research.
present
review
provides
an
outlook
recent
most
common
suggesting
practices
should
have
proceeded
clinical
application.
Chemical Engineering Journal,
Journal Year:
2024,
Volume and Issue:
485, P. 149842 - 149842
Published: Feb. 19, 2024
Healing
bone
defects
in
patients
with
type
2
diabetes
mellitus
(T2DM)
has
long
been
a
challenging
issue.
Elevated
blood
sugar
levels
T2DM
lead
to
the
overproduction
of
reactive
oxygen
species
(ROS),
which
negatively
affects
mitochondrial
function,
induces
senescence
marrow
mesenchymal
stem
cells
(BMSCs),
and
diminishes
their
osteoblastic
potential.
In
this
study,
we
developed
polyacrylic
acid
modified
cerium
oxide
nanoparticles
(PCNPs),
biocompatible,
water-soluble,
antioxidant
nanozyme.
Our
vitro
experiments
demonstrated
that
PCNPs
effectively
eliminated
ROS,
restored
significantly
upregulated
AMPK-SIRT1-PGC1α
signaling
pathway,
ultimately
mitigating
BMSCs
senescence.
Considering
clinical
applications,
have
also
investigated
synergistic
effects
material
systems
for
sustained
release
vivo.
This
sustained-release
system
proved
be
more
effective
promoting
defect
healing
rats.
These
findings
introduce
promising
innovative
approach
managing
using
customized
multifunctional
nanozymes.
Advanced Healthcare Materials,
Journal Year:
2023,
Volume and Issue:
13(1)
Published: Aug. 26, 2023
Abstract
With
the
discovery
of
intrinsic
enzyme‐like
activity
metal
oxides,
nanozymes
garner
significant
attention
due
to
their
superior
characteristics,
such
as
low
cost,
high
stability,
multi‐enzyme
activity,
and
facile
preparation.
Notably,
in
field
biomedicine,
primarily
focus
on
disease
detection,
antibacterial
properties,
antitumor
effects,
treatment
inflammatory
conditions.
However,
potential
for
application
regenerative
medicine,
which
addresses
wound
healing,
nerve
defect
repair,
bone
regeneration,
cardiovascular
treatment,
is
garnering
interest
well.
This
review
introduces
an
innovative
strategy
within
realm
medicine.
The
primary
this
approach
lies
facilitation
osteochondral
regeneration
through
modulation
pathological
microenvironment.
catalytic
mechanisms
four
types
representative
are
first
discussed.
microenvironment
inhibiting
followed
by
summarizing
therapy
mechanism
barriers
introduced.
Further,
therapeutic
diseases
included.
To
improve
efficiency
facilitate
clinical
translation,
future
applications
also
discussed
some
challenges
addressed.
Journal of Functional Biomaterials,
Journal Year:
2023,
Volume and Issue:
14(7), P. 378 - 378
Published: July 19, 2023
Orthopedic
bone
graft
infections
are
major
complications
in
today's
medicine,
and
the
demand
for
antibacterial
treatments
is
expanding
because
of
spread
antibiotic
resistance.
Various
compositions
hydroxyapatite
(HAp)
which
Calcium
(Ca2+)
ions
substituted
with
Cerium
(Ce3+)
Magnesium
(Mg2+)
herein
proposed
as
biomaterials
hard
tissue
implants.
This
approach
gained
popularity
recent
years
and,
pursuit
mimicking
natural
mineral's
composition,
over
70
elements
Periodic
Table
were
already
reported
substituents
into
HAp
structure.
The
current
study
aimed
to
create
materials
based
on
HAp,
Hap-Ce,
Hap-Mg
using
hydrothermal
maturation
microwave
field.
route
has
been
considered
a
novel,
promising,
effective
way
obtain
monodisperse,
fine
nanoparticles
while
easily
controlling
synthesis
parameters.
synthesized
powders
characterized
morphologically
structurally
by
XRD
diffraction,
Dynamic
light
scattering,
zeta
potential,
FTIR
spectrometry,
SEM
analysis.
Proliferation
morphological
analysis
osteoblast
cell
cultures
used
demonstrate
cytocompatibility
produced
biomaterials.
antimicrobial
effect
was
highlighted
samples,
especially
cerium.
Therefore,
samples
cerium
or
magnesium
enhanced
osseointegration,
also
having
capacity
reduce
device-associated
infections.
Advanced Materials,
Journal Year:
2024,
Volume and Issue:
unknown
Published: Aug. 20, 2024
Abstract
Osteosarcoma
is
one
of
the
most
dreadful
bone
neoplasms
in
young
people,
necessitating
development
innovative
therapies
that
can
effectively
eliminate
tumors
while
minimizing
damage
to
limb
function.
An
ideal
therapeutic
strategy
should
possess
three
essential
capabilities:
antitumor
effects,
tissue‐protective
properties,
and
ability
enhance
osteogenesis.
In
this
study,
self‐assembled
Ce‐substituted
molybdenum
blue
(CMB)
nanowheel
crystals
are
synthesized
loaded
onto
3D‐printed
bioactive
glass
(CMB@BG)
scaffolds
develop
a
unique
three‐in‐one
treatment
approach
for
osteosarcoma.
The
CMB@BG
exhibit
outstanding
photothermally
derived
tumor
ablation
within
near‐infrared‐II
window
due
surface
plasmon
resonance
properties
CMB
crystals.
Furthermore,
synergistic
catalytic
effect
promotes
rapid
scavenging
reactive
oxygen
species
caused
by
excessive
heat,
thereby
suppressing
inflammation
protecting
surrounding
tissues.
pro‐proliferation
pro‐differentiation
capabilities
efficiently
accelerate
regeneration
defects.
Altogether,
combine
highly
efficient
ablation,
tissue
protection
based
on
anti‐inflammatory
mechanisms,
enhanced
osteogenic
likely
be
point‐to‐point
solution
comprehensive
needs
Biomedical Materials,
Journal Year:
2025,
Volume and Issue:
20(2), P. 025022 - 025022
Published: Jan. 31, 2025
Direct
pulp
capping
is
crucial
for
maintaining
dental
vitality.
The
materials
employed
this
purpose
should
possess
properties
such
as
easy-handling,
excellent
biocompatibility,
infection
resistance,
and
the
ability
to
stimulate
formation
of
reparative
dentin.
Mineral
trioxide
aggregate
(MTA)
commonly
used
capping.
However,
certain
limitations,
including
its
long
setting
time,
insufficient
anti-washout
ability,
high
initial
curing
pH,
handling
difficulties,
restrict
MTA
from
meeting
a
broader
range
clinical
demands.
Bioactive
glass
(BG)
known
osteo-inductive
bone
restoration
properties.
This
study
aims
develop
novel
BG-based
cement
(BG-x/SA)
applications,
using
BG
microspheres
(BG-x)
solid
phase
sodium
alginate
solution
(SA)
liquid
phase.
has
core-shell
made
byin-situtransformation,
with
in
core
hydroxyapatite
shell.
focuses
on
how
thein-situsynthesis
reaction
parameters
affect
cement's
Ultimately,
BG-6/SA
was
identified
optimal
formulation,
comparison
shows
short
good
performance,
can
adjust
pH
mildly
alkaline,
promotes
dentin
formation,
antibacterial
effects.
Thus,
significant
research
value
prospects
new
pulp-capping
material.
