Regenerative Biomaterials,
Journal Year:
2024,
Volume and Issue:
11
Published: Jan. 1, 2024
Abstract
Biofabrication
techniques
allow
for
the
construction
of
biocompatible
and
biofunctional
structures
composed
from
biomaterials,
cells
biomolecules.
Bioprinting
is
an
emerging
3D
printing
method
which
utilizes
biomaterial-based
mixtures
with
other
biological
constituents
into
printable
suspensions
known
as
bioinks.
Coupled
automated
design
protocols
based
on
different
modes
droplet
deposition,
bioprinters
are
able
to
fabricate
hydrogel-based
objects
specific
architecture
geometrical
properties,
providing
necessary
environment
that
promotes
cell
growth
directs
differentiation
towards
application-related
lineages.
For
preparation
such
bioinks,
various
water-soluble
biomaterials
have
been
employed,
including
natural
synthetic
biopolymers,
inorganic
materials.
Bioprinted
constructs
considered
be
one
most
promising
avenues
in
regenerative
medicine
due
their
native
organ
biomimicry.
a
successful
application,
bioprinted
should
meet
particular
criteria
optimal
response,
mechanical
properties
similar
target
tissue,
high
levels
reproducibility
fidelity,
but
also
increased
upscaling
capability.
In
this
review,
we
highlight
recent
advances
bioprinting,
focusing
regeneration
tissues
bone,
cartilage,
cardiovascular,
neural,
skin
organs
liver,
kidney,
pancreas
lungs.
We
discuss
rapidly
developing
co-culture
bioprinting
systems
used
resemble
complexity
crosstalk
between
populations
regeneration.
Moreover,
report
basic
physical
principles
governing
ideal
bioink
biomaterials’
potential.
examine
critically
present
status
regarding
its
applicability
current
limitations
need
overcome
establish
it
at
forefront
artificial
production
transplantation.
Annals of 3D Printed Medicine,
Journal Year:
2021,
Volume and Issue:
2, P. 100011 - 100011
Published: April 9, 2021
Three-dimensional
(3D)
printing
is
becoming
a
booming
technology
to
fabricate
scaffolds,
orthoses,
and
prosthetic
devices
for
tissue
engineering,
regenerative
medicine,
rehabilitation
patients
with
disabling
neurological
diseases
(such
as
amyotrophic
lateral
sclerosis,
traumatic
brain
injuries,
spinal
cord
injuries).
This
due
the
potential
of
3D
provide
patient-specific
designs,
high
structural
complexity,
rapid
on-demand
fabrication
at
low-cost.
However,
one
major
bottlenecks
that
limits
widespread
acceptance
biomedical
manufacturing
lack
polymers,
biomaterials,
hydrogels,
bioinks
functional
printing,
biocompatible,
more
performing
from
biomechanical
point
view
meet
different
needs.
As
matter
fact
field
still
struggling
processing
such
materials
into
self-supporting
tunable
biomechanics,
optimal
structures,
degradation,
bioactivity.
Here,
will
be
highlighted
all
recent
advances
have
been
made
in
biomedicine,
analyzing
bioinks,
according
their
printability,
ease
processability,
cost,
properties
mechanics,
biocompatibility,
degradation
rate.
Finally,
future
considerations
bio-fabrication
discussed.
International Journal of Pharmaceutics,
Journal Year:
2022,
Volume and Issue:
615, P. 121506 - 121506
Published: Jan. 24, 2022
One
of
the
exciting
future
directions
in
3D
printing
field
is
development
innovative
personalized
smart
constructions
for
bio-applications,
including
drug
delivery,
namely
high-throughput
screening
and
customized
topical/oral
administration
pharmaceuticals,
as
well
tissue
engineering.
In
this
context,
hydrogels
have
emerged
a
promising
material
that,
when
combined
with
extrusion
printing,
allow
creation
soft-material
structures
defined
spatial
locations,
that
can
be
printed
at
room
temperature
by
tuning
geometric
design
and/or
formulation
components.
Thus,
efficacy
quality
such
vehicles
dependent
on
formulation,
design,
process
parameters.
However,
hydrogel
inks
are
often
designed
characterized
using
different
methods
lack
uniformity
impairs.
Characterization
techniques
usually
arbitrary
differ
among
research
groups,
challenging
inference
possible
conclusions
behaviour
potential
applications.
Therefore,
to
properly
analyse
particular
ink
we
review,
first
time,
most
frequently
employed
characterization
procedures,
from
rheological
approaches
parameters
settings,
discuss
their
relevance,
limitations
drawbacks,
highlight
perspectives.
Overall,
accelerate
high-quality
constructs,
comprehensive
protocols
both
pre-printing
assays
should
adopted.
Furthermore,
transversal
adoption
could
serve
boost
terms
requirements
regulatory
aspects.
Bioactive Materials,
Journal Year:
2022,
Volume and Issue:
19, P. 292 - 327
Published: April 23, 2022
Fabrication
of
functional
scaffolds
for
tissue
engineering
and
regenerative
medicine
applications
requires
material
systems
with
precise
control
over
cellular
performance.
3D
printing
is
a
powerful
technique
to
create
highly
complex
multicomponent
structures
well-defined
architecture
composition.
In
this
review
paper,
we
explore
extrusion-based
methods
(EBP,
i.e.,
Near
Field
Electrospinning
(NFES),
Melt
Electrowriting
(MEW),
Fused
Deposition
Modeling
(FDM),
extrusion
bioprinting)
in
terms
their
ability
produce
bio-instructive
properties.
These
provide
spatio-temporal
guidance
cells,
allowing
controlled
regeneration
maturation.
Multiple
physical
biochemical
cues
introduced
the
EBP
are
evaluated
direct
cell
alignment,
proliferation,
differentiation,
specific
ECM
production,
We
indicate
that
have
different
impacts
depending
on
system,
type
used,
or
coexistence
multiple
cues.
Therefore,
they
must
be
carefully
chosen
based
targeted
application.
propose
future
directions
materials
development,
including
such
concepts
as
metamaterials,
hybrid
living
materials,
4D
printing.
The
gathers
knowledge
essential
designing
new
response,
fabrication
advanced
engineered
tissue,
developing
better
understanding
biology,
especially
response
biomaterial.
Advanced Materials,
Journal Year:
2023,
Volume and Issue:
35(26)
Published: Jan. 12, 2023
Abstract
Cartilage
degeneration
is
among
the
fundamental
reasons
behind
disability
and
pain
across
globe.
Numerous
approaches
have
been
employed
to
treat
cartilage
diseases.
Nevertheless,
none
shown
acceptable
outcomes
in
long
run.
In
this
regard,
convergence
of
tissue
engineering
microfabrication
principles
can
allow
developing
more
advanced
microfluidic
technologies,
thus
offering
attractive
alternatives
current
treatments
traditional
constructs
used
applications.
Herein,
developments
involving
hydrogel‐based
scaffolds,
promising
structures
for
regeneration,
ranging
from
hydrogels
with
channels
prepared
by
devices,
that
enable
therapeutic
delivery
cells,
drugs,
growth
factors,
as
well
cartilage‐related
organ‐on‐chips
are
reviewed.
Thereafter,
anatomy
types
damages,
present
treatment
options
briefly
overviewed.
Various
introduced,
advantages
scaffolds
over
thoroughly
discussed.
Furthermore,
available
technologies
fabricating
chips
presented.
The
preclinical
clinical
applications
regeneration
development
time
further
explained.
developments,
recent
key
challenges,
prospects
should
be
considered
so
develop
systems
repair
highlighted.
Journal of Functional Biomaterials,
Journal Year:
2023,
Volume and Issue:
14(9), P. 455 - 455
Published: Sept. 3, 2023
Biomaterials
are
at
the
forefront
of
future,
finding
a
variety
applications
in
biomedical
field,
especially
wound
healing,
thanks
to
their
biocompatible
and
biodegradable
properties.
Wounds
spontaneously
try
heal
through
series
interconnected
processes
involving
several
initiators
mediators
such
as
cytokines,
macrophages,
fibroblasts.
The
combination
biopolymers
with
healing
properties
may
provide
opportunities
synthesize
matrices
that
stimulate
trigger
target
cell
responses
crucial
process.
This
review
outlines
optimal
management
care
required
for
treatment
special
focus
on
biopolymers,
drug-delivery
systems,
nanotechnologies
used
enhanced
applications.
Researchers
have
utilized
range
techniques
produce
dressings,
leading
products
different
characteristics.
Each
method
comes
its
unique
strengths
limitations,
which
important
consider.
future
trajectory
dressing
advancement
should
prioritize
economical
eco-friendly
methodologies,
along
improving
efficacy
constituent
materials.
aim
this
work
is
give
researchers
possibility
evaluate
proper
materials
preparation
better
understand
synthesis
conditions
well
most
effective
bioactive
molecules
load.
Annals of Microbiology,
Journal Year:
2023,
Volume and Issue:
73(1)
Published: April 10, 2023
Abstract
Purpose
The
textile
industry’s
previous
chemical
use
resulted
in
thousands
of
practical
particulate
emissions,
such
as
machine
component
damage
and
drainage
system
blockage,
both
which
have
implications.
Enzyme-based
processing
is
cost-effective,
environmentally
friendly,
non-hazardous,
water-saving.
purpose
this
review
to
give
evidence
on
the
potential
activity
microbial
cellulase
industry,
mostly
confined
realm
research.
Methods
This
was
progressive
by
considering
peer-reviewed
papers
linked
production,
its
prospective
application
for
industries
appraised
produced
develop
assessment.
Articles
were
divided
into
two
categories
based
results
trustworthy
educational
journals:
methods
used
produce
diversity
microorganisms
through
fermentation
processes
approaches
microbes
fermentation.
Submerged
(SMF)
solid-state
(SSF)
techniques
are
currently
being
meet
industrial
demand
production
bio
industry.
Results
Microbial
vital
increasing
day
due
no
side
effect
environment
human
health
becoming
increasingly
important.
In
conventional
processing,
gray
cloth
subjected
a
series
treatments
that
involved
breaking
dye
molecule’s
amino
group
with
Cl
−
,
started
accelerated
dye(-resistant)
bond
cracking.
A
enzyme
primarily
derived
from
variety
species
found
various
ecological
settings
biotextile/bio-based
product
technology
future
needs
applications.
Conclusion
Cellulase
has
been
advantages
cellulose-based
textiles,
well
quality
enhancement
fabric
maintenance
over
traditional
approaches.
Cellulase’s
role
industry
chosen
an
appropriate
sound
solution
long
healthy
lifestyle.
Additive manufacturing,
Journal Year:
2024,
Volume and Issue:
84, P. 104094 - 104094
Published: March 1, 2024
Volumetric
Additive
Manufacturing
(VAM)
is
an
emerging
3D
printing
technology
that
operates
by
fabricating
objects
from
all
points
within
a
medium's
volume.
This
technique
capable
of
producing
parts
without
supporting
structures
and
overprinting
around
existing
structures.
Notably,
the
approach
VAM
utilises
to
print
time
efficient
compared
traditional
additive
manufacturing
methods
with
times
being
measured
in
seconds
minutes
instead
hours.
As
this
there
little
comparison
or
synthesis
reported
so
far
literature,
thus
primary
objective
review
address
issue
providing
comprehensive
analysis
VAM,
delving
into
its
applications,
challenges
it
faces,
research
advancements
made
area.
also
investigates
how
new
are
investigated
on,
literature.
In
order
achieve
goal
structured
literature
was
conducted
thoroughly
examine
current
state
VAM.
found
30
papers,
which
were
used
categorise
different
methods,
explore
potential
various
fields,
formulate
definition
for
differentiate
other
technologies.
A
key
finding
while
offers
rapid
fabrication
capabilities,
currently
faces
several
constraints.
These
include
limited
availability
commercial
printers,
complex
methodologies,
restricted
range
compatible
materials,
need
specialised
equipment.
Collectively,
these
factors
could
serve
as
barriers
broader
adoption
technology.
addition,
lack
homogeneity
parameters
investigate
report
makes
difficult
compare
contrast
works
against
published
field
progresses,
addressing
will
be
essential
unlock
applications
increase
one
first
explicitly
focus
on
entirety
offering
valuable
insights
present
directions
future
research.
