Bibliometric analysis of additive manufacturing in cranial and craniofacial implant research
Journal of Cranio-Maxillofacial Surgery,
Год журнала:
2025,
Номер
unknown
Опубликована: Фев. 1, 2025
Язык: Английский
The rise of 3D bioprinting: from organs to personalized medicine
Patient-Oriented Medicine and Pharmacy,
Год журнала:
2025,
Номер
unknown
Опубликована: Март 7, 2025
Bioprinting
has
emerged
as
a
groundbreaking
technology
in
the
realms
of
organ
transplantation
and
regenerative
medicine,
addressing
critical
challenges
such
shortages
tissue
repair.
This
review
explores
technological
advancements
innovations
bioprinting,
highlighting
state-of-the-art
techniques,
bioinks,
applications
engineering.
Key
milestones
printing
functional
tissues,
including
vascularized
transplantable
prototypes,
are
discussed
alongside
role
bioprinting
personalized
where
patient-oriented
models
revolutionizing
drug
testing
therapeutic
strategies.
Furthermore,
this
article
examines
ethical
considerations
associated
with
offering
insights
into
its
future
potential
to
transform
global
healthcare.
Язык: Английский
The Next Frontier in Aesthetics: 3D Bioprinting for Personalized Skin Regeneration
Journal of Cosmetic Dermatology,
Год журнала:
2025,
Номер
24(4)
Опубликована: Март 26, 2025
Cosmetic
dermatology
is
entering
a
new
frontier
with
the
advent
of
3D
bioprinting,
technology
poised
to
revolutionize
way
we
approach
skin
regeneration,
aesthetic
enhancement,
and
personalized
dermatologic
interventions
[1].
While
initially
developed
for
reconstructive
applications,
bioprinted
may
soon
redefine
anti-aging
treatments,
scar
revision,
even
volumetric
facial
rejuvenation.
The
ability
print
customized
grafts
using
patient's
own
cells
presents
an
unprecedented
opportunity
natural,
long-lasting
results
that
go
beyond
current
injectables
or
energy-based
devices
[2].
Unlike
synthetic
fillers
collagen
stimulators,
bioengineered
has
potential
integrate
seamlessly
native
tissue,
not
just
restoring
lost
elasticity
improving
texture
but
also
offering
truly
volume
restoration
wrinkle
repair.
development
bioinks
composed
extracellular
matrix
components,
fibroblasts,
keratinocytes
made
it
possible
recreate
full-thickness
layers,
closely
mimicking
natural
architecture
[3].
This
breakthrough
paves
regenerative
therapies
tailored
unique
biology,
major
leap
from
primarily
focus
on
temporary
improvements.
Recent
studies
have
already
explored
possibility
bioprinting
constructs
replicate
biomechanical
pigmentation
properties,
which
could
provide
highly
solutions
ethnic
tones,
hyperpigmentation
disorders,
remodeling
[1,
4].
be
game
changer
in
treating
post-inflammatory
hyperpigmentation,
vitiligo,
burn
scars,
where
uniform
repigmentation
remains
significant
challenge.
What
if,
instead
depigmentation
camouflage
techniques,
bioprint
new,
pigment-matched
skin?
implications
are
enormous.
Beyond
direct
holds
promise
testing
cosmetic
formulations,
optimizing
post-procedure
recovery,
hosting
patient-specific
microbiomes.
Traditional
vitro
models
lack
complexity
real
skin,
limiting
predict
how
skincare
products,
fillers,
treatments
will
interact
human
tissue.
Bioprinted
bridge
this
gap,
serving
as
functional
platforms
eliminate
need
animal
more
accurate
insights
into
product
safety
efficacy
[5].
With
AI-driven
modeling,
future
regeneration
becomes
precise.
AI-assisted
tissue
engineering
optimize
scaffold
design,
ensuring
enhance
synthesis,
modulate
inflammation,
restore
dermal
[6].
manage
atrophic
keloids,
aging-related
loss,
moving
us
away
toward
long-term
regeneration.
possibilities
vast,
yet
surprisingly
underexplored
research.
Despite
its
promise,
raises
critical
questions
about
regulatory
pathways,
accessibility,
ethical
considerations.
Will
these
classified
medical
luxury
enhancements?
Could
customized,
youthful
fuel
unrealistic
expectations
medicine?
designer
aesthetics
shaping
beauty
trends
through
consultations,
far
patients
requesting
modifications
idealized
standards
rather
than
restoration?
These
dermatologists,
researchers,
policymakers
must
address
continues
advance.
Another
challenge
cost
accessibility.
widely
available,
expensive
largely
experimental.
become
niche
service
reserved
high-end
clinics,
advancements
biofabrication
make
scalable
accessible
broader
population?
considerations
taken
account
transitions
lab
clinical
practice.
field
continually
evolving,
now
time
start
conversation
reshape
treatment
paradigms.
create
personalized,
exciting
challenge,
one
lead
fundamental
shift
medicine.
As
progresses,
interdisciplinary
collaboration
crucial
bridging
gap
between
medicine,
dermatology,
biotechnology.
medicine
reversing
time,
bioengineering
evolve
it.
However,
further
research
essential
fully
understand
efficacy,
safety,
applications.
author
declares
no
conflicts
interest.
data
support
findings
study
available
references'
part.
Язык: Английский
Advances in bioink-based 3D printed scaffolds: optimizing biocompatibility and mechanical properties for bone regeneration
Biomaterials Science,
Год журнала:
2025,
Номер
unknown
Опубликована: Янв. 1, 2025
The
development
of
bioink-based
3D-printed
scaffolds
has
revolutionized
bone
tissue
engineering
(BTE)
by
enabling
patient-specific
and
biomimetic
constructs
for
regeneration.
Язык: Английский
3D Bioprinting: Shaping the Future of Periodontal Tissue Regeneration and Disease Management
Cureus,
Год журнала:
2025,
Номер
unknown
Опубликована: Апрель 17, 2025
The
periodontium
is
one
of
the
most
complex
tissues
in
body,
consisting
a
hierarchical
blend
soft
and
hard
tissues.
Its
architecture
makes
treating
regenerating
disease-damaged
periodontal
persistent
challenge
biomedicine.
Three-dimensional
(3D)
bioprinting
represents
transformative
approach
to
tissue
engineering,
offering
promising
advancements
disease.
This
innovative
technology
enables
precise
fabrication
complex,
patient-specific
structures,
facilitating
repair
restoration
damaged
tissues,
including
gingiva,
bone,
ligament
(PDL).
By
utilizing
biocompatible
materials
such
as
living
cells,
hydrogels,
growth
factors,
3D
has
potential
create
functional,
biologically
integrated
constructs
that
can
mimic
natural
However,
translating
these
into
clinical
applications
remains
challenge.
Emerging
technologies
like
have
been
developed
address
some
limitations
traditional
engineering
methods.
review
explores
current
state
technology,
its
application
disease
treatment,
challenges
associated
with
scaling
up
this
for
use.
Additionally,
it
discusses
future
implications
personalized
medicine,
new
frontier
improving
patient
outcomes
oral
health.
Integrating
regenerative
therapies
could
revolutionize
practices,
more
effective,
tailored,
sustainable
solutions
Язык: Английский