Metals,
Journal Year:
2023,
Volume and Issue:
13(3), P. 490 - 490
Published: Feb. 27, 2023
The
concept
of
repair
and
restoration
using
additive
manufacturing
(AM)
is
to
build
new
metal
layers
on
a
broken
part.
It
beneficial
for
complex
parts
that
are
no
longer
available
in
the
market.
Optimization
methods
used
solve
product
design
problems
produce
efficient
highly
sustainable
products.
Design
optimization
can
improve
efficiency
process
during
end-of-life
(EoL)
phase.
In
this
paper,
objective
review
strategies
remanufacturing
products
or
at
EoL
phase
facilitate
AM.
important
reduce
time.
This
paper
focuses
main
challenges
constraints
AM
restoration.
Various
AI
techniques,
including
hybrid
method
be
integrated
into
AM,
analyzed
presented.
highlights
research
gap
provides
recommendations
future
directions.
conclusion,
combination
artificial
neural
network
(ANN)
algorithms
with
genetic
as
key
solution
solving
limitations
manufacturing.
Global Health Journal,
Journal Year:
2022,
Volume and Issue:
6(4), P. 217 - 226
Published: Nov. 3, 2022
There
is
a
growing
demand
for
customised,
biocompatible,
and
sterilisable
components
in
the
medical
business.
3D
Printing
disruptive
technology
healthcare
provides
significant
research
development
avenues.
Simple
printing
service
gives
patients
low-cost
individualised
prostheses,
implants,
gadgets,
enabling
surgeons
to
operate
more
effectively
with
customised
equipment
models;
assisting
device
manufacturers
developing
new
faster
goods.
printed
tissue
pieces
can
overcome
various
challenges
may
eventually
allow
medication
companies
streamline
development.
In
long
run,
it
also
assist
lowering
prices
making
medicines
accessible
effective
everybody.
corpus
of
on
advantages
employing
anatomic
models
teaching
training.
The
capacity
individual
anatomical
diseases
practical
learning
one
fundamental
contrasts
between
utilising
regular
models.
very
appealing
producing
patient-specific
implants.
This
literature
review-based
paper
explores
role
bioprinting
healthcare.
It
briefs
need
progressive
steps
implementing
presented
facilities
enablers
sector.
Finally,
this
identifies
discusses
applications
services
be
deployed
easily
construct
complex
geometries
plastic
or
metal
good
precision.
results
improved
prototypes,
lower
costs,
part
processing
times.
They
now
physically
create
natural
materials,
previously
unattainable
prior
technologies.
Every
hospital
should
have
printers
future,
allowing
organs/parts
developed
in-house.
Processes,
Journal Year:
2021,
Volume and Issue:
9(9), P. 1495 - 1495
Published: Aug. 25, 2021
Owing
to
COVID-19,
the
world
has
advanced
faster
in
era
of
Fourth
Industrial
Revolution,
along
with
3D
printing
technology
that
achieved
innovation
personalized
manufacturing.
Three-dimensional
been
utilized
across
various
fields
such
as
environmental
fields,
medical
systems,
and
military
materials.
Recently,
food
printer
global
market
shown
a
high
annual
growth
rate
is
huge
industry
approximately
one
billion
dollars.
can
be
applied
ranges
based
on
advantages
designing
existing
suit
one’s
taste
purpose.
Currently,
many
countries
worldwide
produce
printers,
developing
special
foods
combat
food,
space
restaurants,
floating
elderly
food.
Many
people
are
unaware
utilization
it
its
early
stages.
There
cases
using
parts
world.
expected
become
new
trend
normal
after
COVID-19.
Compared
other
industries,
relatively
small
overall
size
because
problems
insufficient
institutionalization
limitation
standardized
materials
for
printing.
In
this
review,
current
industrial
status
was
investigated
suggestions
improvement
era.
Materials Today Bio,
Journal Year:
2023,
Volume and Issue:
23, P. 100792 - 100792
Published: Sept. 15, 2023
Artificial
intelligence
(AI)
and
3D
printing
will
become
technologies
that
profoundly
impact
humanity.
of
patient-specific
organ
models
is
expected
to
replace
animal
carcasses,
providing
scenarios
simulate
the
surgical
environment
for
preoperative
training
educating
patients
propose
effective
solutions.
Due
complexity
manufacturing,
it
still
used
on
a
small
scale
in
clinical
practice,
there
are
problems
such
as
low
resolution
obtaining
MRI/CT
images,
long
consumption
time,
insufficient
realism.
AI
has
been
effectively
powerful
problem-solving
tool.
This
paper
introduces
printed
models,
focusing
idea
application
manufacturing
models.
Finally,
potential
3D-printed
discussed.
Based
synergy
between
benefit
model
facilitate
medical
field,
use
making
reality.
F1000Research,
Journal Year:
2023,
Volume and Issue:
12, P. 1179 - 1179
Published: Sept. 20, 2023
Artificial
Intelligence
(AI)
technologies
play
a
significant
role
and
significantly
impact
various
sectors,
including
healthcare,
engineering,
sciences,
smart
cities.
AI
has
the
potential
to
improve
quality
of
patient
care
treatment
outcomes
while
minimizing
risk
human
error.
Artificial
is
transforming
dental
industry,
just
like
it
revolutionizing
other
sectors.
It
used
in
dentistry
diagnose
diseases
provide
recommendations.
Dental
professionals
are
increasingly
relying
on
technology
assist
diagnosis,
clinical
decision-making,
planning,
prognosis
prediction
across
ten
specialties.
One
most
advantages
its
ability
analyze
vast
amounts
data
quickly
accurately,
providing
with
valuable
insights
enhance
their
decision-making
processes.
The
purpose
this
paper
identify
advancement
artificial
intelligence
algorithms
that
have
been
frequently
assess
how
well
they
perform
terms
treatment,
specialties;
public
health,
endodontics,
oral
maxillofacial
surgery,
medicine
pathology,
&
radiology,
orthodontics
dentofacial
orthopedics,
pediatric
dentistry,
periodontics,
prosthodontics,
digital
general.
We
will
also
show
pros
cons
using
all
specialties
different
ways.
Finally,
we
present
limitations
which
made
incapable
replacing
personnel,
dentists,
who
should
consider
complimentary
benefit
not
threat.
Applied Sciences,
Journal Year:
2023,
Volume and Issue:
13(2), P. 1060 - 1060
Published: Jan. 12, 2023
Three-dimensional-printed
medical
devices
are
a
separate
group
of
necessary
for
the
development
personalized
medicine.
The
present
article
discusses
modern
and
specific
exoskeletons,
which
aims
to
our
own
experiences
in
selection
materials,
design,
artificial-intelligence
optimization,
production,
testing
several
generations
various
upper
limb
exoskeletons
when
considering
Medical
Devices
Regulation
(MDR)
ISO
13485
10993
standards.
Work
is
underway
maintain
methodological
rigor
inherent
develop
new
business
models
achieve
cost-effectiveness
so
that
inadequate
legislation
does
not
stop
this
technologies
(3D
scanning,
3D
printing,
reverse
engineering)
healthcare
system.
gap
between
research
engineering
practice
clinical
printing
should
be
bridged
as
quickly
carefully
possible.
This
measure
will
ensure
transfer
proven
solutions
into
practice.
growing
maturity
technology
increasingly
impact
everyday
practice,
it
prepare
specialists
strategic
organizational
changes
realize
correct
implementation
based
on
needs
patients
clinicians.