Dentistry,
Journal Year:
2025,
Volume and Issue:
unknown
Published: Feb. 13, 2025
Traumatic
dental
injuries
(TDIs)
represent
a
significant
global
healthcare
challenge,
affecting
different
age
groups
and
socioeconomic
strata.
This
comprehensive
chapter
presents
contemporary
advances
in
diagnosing,
managing,
preventing
TDIs,
integrating
evidence-based
approaches
with
emerging
technologies
biological
interventions.
The
text
systematically
addresses
the
multifaceted
nature
of
trauma,
from
immediate
emergency
response
to
long-term
rehabilitation,
while
considering
broader
implications
for
systems
society.
Recent
developments
diagnostic
technologies,
including
artificial
intelligence-assisted
imaging
advanced
assessment
tools,
have
transformed
initial
evaluation
trauma.
explores
innovative
treatment
modalities,
encompassing
regenerative
endodontics,
stem
cell
applications,
computer-guided
interventions
alongside
traditional
approaches.
Particular
emphasis
is
placed
on
digital
workflows,
teledentistry
minimally
invasive
techniques
that
revolutionized
trauma
management.
critically
examines
impact
TDI,
direct
indirect
costs,
quality
life
considerations,
resource
allocation.
Special
attention
given
age-specific
management
protocols,
medically
compromised
patients,
legal-ethical
considerations.
concludes
an
analysis
future
directions
traumatology,
providing
framework
continued
advancement.
Bioengineering,
Journal Year:
2023,
Volume and Issue:
11(1), P. 32 - 32
Published: Dec. 27, 2023
Notably,
3D-printed
flexible
and
wearable
biosensors
have
immense
potential
to
interact
with
the
human
body
noninvasively
for
real-time
continuous
health
monitoring
of
physiological
parameters.
This
paper
comprehensively
reviews
progress
in
biosensors.
The
review
also
explores
incorporation
nanocomposites
3D
printing
A
detailed
analysis
various
processes
fabricating
is
reported.
Besides
this,
recent
advances
platforms
such
as
sweat
sensors,
glucose
electrocardiography
electroencephalography
tactile
oximeters,
tattoo
respiratory
sensors
are
discussed.
Furthermore,
challenges
prospects
associated
presented.
an
invaluable
resource
engineers,
researchers,
healthcare
clinicians,
providing
insights
into
advancements
capabilities
biosensor
domain.
The International Journal of Advanced Manufacturing Technology,
Journal Year:
2024,
Volume and Issue:
131(3-4), P. 1289 - 1301
Published: Feb. 6, 2024
Abstract
The
topological
optimization
of
components
by
means
lattice
structures
allows
to
reduce
their
weight
avoiding
a
loss
in
the
mechanical
performance.
Often
parts
are
integrated
more
complex
geometry,
and
they
present
an
interface
with
solid
part.
In
paper,
microstructural
characterization
Ti6Al4V
body-centered
cubic
unit
cell
was
carried
out.
Samples
without
external
shell
were
designed
produced
electron
beam
powder
bed
fusion
order
investigate
behavior
these
structures,
especially
at
between
parts.
microstructure
defects
analyzed,
compression
tests
performed
on
samples
understand
influence
part
its
interaction
structure.
After
fracture
detachment
shell,
same
for
both
set
observed.
Finally,
finite
element
model
defined
better
investigated
structures.
nominal
sample
stiffness
significantly
higher
than
experimental
one.
This
discrepancy
can
be
attributed
local
defects,
terms
porosities
deviations
from
ideal
geometry.
Materials,
Journal Year:
2024,
Volume and Issue:
17(17), P. 4255 - 4255
Published: Aug. 28, 2024
Today,
smart
materials
are
commonly
used
in
various
fields
of
science
and
technology,
such
as
medicine,
electronics,
soft
robotics,
the
chemical
industry,
automotive
field,
many
others.
Smart
polymeric
hold
good
promise
for
future
due
to
their
endless
possibilities.
This
group
advanced
can
be
sensitive
changes
or
presence
chemical,
physical,
biological
stimuli,
e.g.,
light,
temperature,
pH,
magnetic/electric
pressure,
microorganisms,
bacteria,
viruses,
toxic
substances,
review
concerns
newest
achievements
area
materials.
The
recent
advances
designing
stimuli-responsive
polymers
described
this
paper.
Polymer Reviews,
Journal Year:
2024,
Volume and Issue:
unknown, P. 1 - 65
Published: Nov. 20, 2024
The
biomedical
industry
has
witnessed
a
transformative
evolution
with
the
advent
of
3D
printing
technology.
However,
inherent
limitations,
such
as
inability
to
produce
dynamic
human
tissues
due
absence
temporal
dimension,
have
persisted,
resulting
in
static
and
inanimate
printed
products.
To
address
this
challenge
enable
creation
living
constructs,
concept
4D
emerged,
marking
paradigm
shift
additive
manufacturing.
In
printing,
time
becomes
fourth
breathing
life
into
previously
creations.
This
review
paper
explores
journey
from
pivotal
role
manufacturing
process.
Specifically,
it
highlights
integration
time-dependent
responsive
materials,
focusing
on
stimuli-responsive
hydrogels,
cornerstone
advancements.
These
materials
exhibit
remarkable
ability
adapt
respond
various
stimuli,
encompassing
physical,
chemical,
biological
signals.
delves
recent
publications
synergy
between
these
stimuli
shedding
light
their
intricate
interactions
potential
applications.
One
primary
areas
interest
lies
medical
applications,
notably
tissue
engineering,
where
holds
immense
promise.
utilization
creating
biomimetic
scaffolds
that
can
dynamically
complex
environments.
Furthermore,
discusses
technical
considerations
prospects
technology,
emphasizing
its
revolutionize
landscape.
amalgamation
opens
new
avenues
for
personalized
medicine,
localized
drug
delivery,
regenerative
therapies,
bridging
gap
requirements
modern
healthcare.
present
offers
complete
examination
evolution,
challenges,
paving
way
innovations
field.
Frontiers in Bioengineering and Biotechnology,
Journal Year:
2024,
Volume and Issue:
12
Published: March 13, 2024
Bio-printed
hydrogels
have
evolved
as
one
of
the
best
regenerative
medicine
and
tissue
engineering
platforms
due
to
their
outstanding
cell-friendly
microenvironment.
A
correct
hydrogel
ink
formulation
is
critical
for
creating
desired
scaffolds
that
better
fidelity
after
printing.
Gelatin
its
derivatives
sparked
intense
interest
in
various
biomedical
sectors
because
biocompatibility,
biodegradability,
ease
functionalization,
rapid
gelling
tendency.
As
a
result,
this
report
emphasizes
relevance
gelatin-based
fabricating
bio-printed
orthopedic
applications.
Starting
with
what
bio-printing
are
all
about.
We
further
summarized
different
techniques
explored
applications,
including
few
recent
studies.
also
discussed
suitability
gelatin
biopolymer
both
3D
4D
printing
materials.
extrusion
most
widely
used
gelatin-based,
we
summarize
rheological
features
bio-ink.
Lastly,
elaborate
on
studies
orthopedics
potential
clinical
translation
issues,
research
possibilities.
Polymers for Advanced Technologies,
Journal Year:
2024,
Volume and Issue:
35(12)
Published: Dec. 1, 2024
ABSTRACT
This
review
provides
a
comprehensive
overview
of
the
emerging
applications
stimuli‐responsive
hydrogels
in
3D
printing,
emphasizing
their
transformative
potential
creating
adaptive
and
multifunctional
structures.
Stimuli‐responsive
hydrogels,
including
magneto‐,
thermo‐,
pH‐,
moisture‐,
solvent‐,
photo‐responsive
varieties,
have
gained
significant
attention
due
to
ability
undergo
dynamic
changes
response
specific
environmental
stimuli.
The
begins
by
exploring
fundamental
characteristics
fabrication
methods
used
additive
manufacturing,
highlighting
exceptional
adaptability
programmability.
It
then
delves
into
various
across
diverse
fields,
soft
robotics,
tissue
engineering,
drug
delivery
systems,
wearable
electronics,
food
technology,
electromagnetic
interference
shielding,
anti‐counterfeiting
technologies.
By
integrating
latest
advancements
printing
techniques,
this
aims
offer
insights
how
are
enabling
development
innovative,
intelligent,
environmentally
responsive
systems.
future
perspectives
section
discusses
challenges
opportunities
for
advancing
use
suggesting
directions
research
that
could
push
boundaries
functional
materials
programmable
Bioengineering,
Journal Year:
2025,
Volume and Issue:
12(1), P. 71 - 71
Published: Jan. 15, 2025
Three-dimensional
printing
was
introduced
in
the
1980s,
though
bioprinting
started
developing
a
few
years
later.
Today,
3D
is
making
inroads
medical
fields,
including
production
of
biomedical
supplies
intended
for
internal
use,
such
as
biodegradable
staples.
Medical
enables
versatility
and
flexibility
on
demand
able
to
modify
individualize
using
several
established
methods.
A
great
selection
biomaterials
bioinks
available,
natural,
synthetic,
mixed
options;
they
are
biocompatible
non-toxic.
Many
accommodate
cells
so
upon
implantation,
integrate
within
new
environment.
Bioprinting
suitable
tissues
living
or
viable
components,
collagen
scaffolding,
cartilage
cells,
also
parts
structures,
teeth,
artificial
man-made
materials
that
will
become
embedded
vivo.
an
integral
part
tissue
engineering
regenerative
medicine.
The
addition
newly
developed
smart
capable
incorporating
dynamic
changes
shape
depending
nature
stimuli
led
fourth
dimension
time
form
changing
three
static
dimensions.
Four-dimensional
already
significant
medicine,
ways
create
tissues.
Its
future
lies
constructing
partial
whole
organ
generation.
