Advanced Functional Materials,
Journal Year:
2024,
Volume and Issue:
unknown
Published: Oct. 27, 2024
Abstract
Since
the
advent
of
3D
printing
technology,
a
significant
effort
has
been
made
to
develop
new
printable
materials.
Despite
recent
progress
in
field
printing,
limited
availability
photoactive
resins
motivated
continuous
research
endeavors
novel
photoresins
with
multifunctional
capabilities.
Herein
biobased
photoresin
derived
is
reported
from
modified
olive
oil,
designed
for
high‐resolution
solvent‐free
4D
The
physicochemical
properties
printed
polymers
are
fine‐tuned
using
acrylic
acid
as
diluent
cum
comonomer.
mechanical
similar
various
soft
tissues,
such
ligaments,
articular
cartilage,
and
collagenous
bone,
showcasing
its
potential
tissue
engineering
applications.
While
excellent
temperature‐responsive
shape
memory
attributes
coupled
exceptional
antimicrobial
toward
gram‐negative
gram‐positive
bacteria
highlight
nature
polymers.
Moreover,
exhibited
outstanding
hemocompatibility
good
cytocompatibility
mouse
fibroblast
cells,
suggesting
their
In
sum,
newly
developed
resin
can
be
employed
minimize
environmental
impact
additive
manufacturing
while
being
competitive
existing
fossil‐based
photoresins,
thereby
meeting
growing
demand
advanced
superior
smart
biomedical
Applied Research,
Journal Year:
2024,
Volume and Issue:
3(4)
Published: Feb. 13, 2024
Abstract
Myco
degradation
is
an
effective
technique
for
breaking
down
waste
plant
substances
made
of
lignin,
cellulose,
and
hemicellulose,
which
are
collectively
known
as
lignocellulose.
This
abundant
organic
material
found
throughout
the
world.
Due
to
its
recalcitrant
nature,
lignocellulose
poses
a
challenge
efficient
conversion
into
biofuels,
biochemicals,
other
valuable
products.
degradation,
involves
use
fungi
degrade
lignocellulosic
materials,
offers
sustainable
cost‐efficient
resolution
this
challenge.
review
provides
overview
mechanisms
applications
myco
biomass
degradation.
The
discusses
various
types
involved
in
their
enzymatic
systems,
factors
that
influences
performance.
Furthermore,
potential
products,
such
enzymes,
bioplastics,
reviewed.
It
also
highlights
implications
management
development.
Overall,
represents
promising
technology
deprivation
biomass,
further
research
field
holds
great
creation
bio‐based
Cleaner and Circular Bioeconomy,
Journal Year:
2024,
Volume and Issue:
8, P. 100089 - 100089
Published: May 17, 2024
Global
consumption
of
plastics
has
increased
continuously
in
recent
decades,
leaving
today's
society
with
one
the
most
pressing
environmental
problems,
plastic
pollution.
Current
research
been
focused
on
development
bio-sustainable
products
aim
replacing
use
petroleum-based
polymers
sustainable,
renewable,
and
environmentally
friendly
materials.
In
this
context,
bioplastics
have
emerged,
where
possible
supporting
biodegradability.
The
abundant
polymer
occurring
naturally
is
cellulose
remains
promising
renewable
materials
to
replace
plastic.
This
work
forms
part
a
larger
activity
studying
novel
production
regenerated
using
ionic
liquid
dissolution,
drawing
filler-containing
paper
board
waste
as
raw
material
for
potential
replacement
circular
economy.
Analysis
applied
literature
search
reported
comparing
current
packaging,
generation
packaging
waste,
cardboard
finally
recycling
rate
these
Europe
special
focus
that
either
fails
enter,
or
rejected
during,
classical
process.
Based
data,
commercialisation
regeneration
made
solely
from
volume
failed
enter
standard
recycling,
excluding
single
products,
e.g.,
sanitary,
would
be
able
cover
demand
films
used
no
additional
biomass
principle
needed.
finding
not
only
supports
effort
being
scale-up
process
commercially
but
relieves
pressure
agricultural
land
currently
foreseen
otherwise
needed
extensive
production,
rather
allowing
it
serve
its
main
purpose
food
so
contributing
economy
quest
sustainability
obviating
impact.
Advanced Functional Materials,
Journal Year:
2024,
Volume and Issue:
unknown
Published: June 4, 2024
Abstract
The
abundance
of
plants
as
a
renewable
bioresource
has
captured
the
significant
attention
researchers,
driving
them
to
explore
new
biodegradable
polymeric
materials.
However,
there
are
still
many
biobased
materials
with
untapped
potential,
offering
opportunities
synthesize
novel
polymers
multifunctional
properties.
This
work
provides
unique
solvent
and
catalyst‐free
melt
polycondensation
process
prepare
series
polyesters
using
zingerol
(Zing‐OH),
reduced
form
zingerone,
primary
component
for
first
time.
Briefly,
Zing‐OH
(a
ginger‐based
component)
is
employed
in
conjunction
variety
resources,
such
citric
acid
(CA),
sebacic
(SA),
xylitol
(Xy),
soft
tissue‐like
ZCSX
polyesters.
Fourier‐transform
infrared
(FTIR)
1
H‐nuclear
magnetic
resonance
(NMR)
spectroscopy
used
validate
synthesis
polyesters,
while
thermogravimetric
analysis
(TGA),
differential
scanning
calorimetry
(DSC),
universal
testing
machine
(UTM)
investigate
their
physicochemical
Moreover,
synthesized
polyester's
thermal,
mechanical,
biodegradation
properties
can
be
fine‐tuned
by
simply
varying
feed
ratio.
mechanical
polymer
resemble
various
human
tissues,
including
liver,
uterus,
bladder,
breast,
temporal
nasal
cartilage.
suggests
that
potentially
useful
tissue
engineering
applications.
Furthermore,
polyester
demonstrated
exceptional
recovery
responses
good
shape
memory
behavior
at
ambient
body
temperature.
Additionally,
observed
from
Alamar
blue,
live/dead
assays,
time‐dependent
vitro
wound
images,
antibacterial
activity,
cytocompatibility,
cell
proliferation,
healing
capabilities
against
mouse
fibroblast
cells
(NIH/3T3).
developed
biocompatible
also
exhibits
excellent
hemocompatibility
blood,
indicating
its
potential
use
field
regenerative
medicine.
