International Journal of Food Engineering,
Год журнала:
2025,
Номер
21(5), С. 285 - 303
Опубликована: Май 1, 2025
Abstract
Lipase
has
emerged
as
a
promising
eco-friendly
biocatalyst.
However,
its
free-form
application
is
limited
by
challenges,
such
poor
recovery
and
stability.
Immobilization
presents
an
effective
strategy
to
overcome
these
limitations,
thereby
enhancing
catalytic
performance.
Nevertheless,
lipase
immobilization
not
obstacle-free
either
necessitates
comprehensive
solutions.
The
development
of
novel
techniques
matrix
materials
remains
relatively
underexplored.
This
review
offers
analysis
both
traditional
advanced
enzyme
strategies,
with
focus
on
how
different
carrier
influence
enzymatic
properties
efficiency.
By
discussing
the
diverse
industrial
applications
immobilized
lipases
while
also
outlining
potential
research
trajectories
within
this
domain,
aims
establish
robust
theoretical
framework
for
improving
performance
enzymes.
Furthermore,
innovative
technologies
3D
printing
membrane-based
are
expected
drive
future
advancements,
providing
strong
foundation
engineering
lipases.
Abstract
Wearable
bioelectronics
is
a
promising
next‐generation
technology
for
its
versatility
in
personalized
applications.
Measuring
lactate
one
of
the
growing
trends
wearable
biosensing
research.
To
achieve
this
goal,
enzymes
capable
catalyzing
reactions
involving
must
be
coupled
with
bioelectrode
components,
creating
variety
biodevices
such
as
biosensors,
biofuel
cells,
and
other
devices
harvesting
energy
from
wearers.
This
review
provides
brief
history
noninvasive
minimally
invasive
enzyme‐based
biosensors
biodevices.
We
introduce
key
principles
oxidase
dehydrogenase,
together
immobilization
strategies
efficient
electrical
contacts
between
redox
electrode
supports.
Additionally,
we
discuss
recent
examples
advanced
enzymatic
sensors
elaborate
on
collection
self‐powered
(e.
g.,
triboelectric
nanogenerators,
piezoelectric
devices).
Lastly,
finish
discussions
challenges
developing
provide
our
outlook
prospects
future
directions
compelling
technology.
Polymer Degradation and Stability,
Год журнала:
2023,
Номер
211, С. 110341 - 110341
Опубликована: Март 13, 2023
Biodegradation
of
polyesters
driven
by
enzymes
is
considered
as
one
the
most
effective
way
degradation
these
materials,
a
to
control
plastics
accumulation
in
environment.
In
this
study,
we
present
two
different
strategies
tune
enzymatic
PBS
films
triggered
lipase
from
Pseudomonas
cepacia.
Firstly,
kinetics
was
regulated
applying
multilayer
coats
polysaccharide
alginate
and
chitosan
(Alg/Chi)
films.
Secondly,
self-degradable
were
prepared
embedding
lipase-filled
particles.
For
comparison
purposes,
detailed
study
neat
exposed
P.
cepacia
solution
made
determine
main
experimental
parameters
influencing
their
solution.
The
results
showed
that
an
increase
enzyme
concentration
increased
extent
rate
At
fixed
concentration,
stirring
containing
also
biodegradation
rate.
case
coated
with
number
Alg/Chi
layers
spray-assisted
LbL
subjected
experiments
solution,
found
be
dependent
on
protective
coating
layers.
Therefore,
biobased
constitutes
barrier
diffusion
lipase,
thus
proving
its
effectiveness
modulating
activity
function
thickness.
lipase-embedded
beads
(employed
protect
during
high-temperature
processing),
only
limited
observed
amount
encapsulated
employed
too
small.
Nonetheless,
are
promising,
–indicative
capacity
enzyme–
determined
for
all
samples
about
2
orders
magnitude
lower
than
previous
assays.
