Molecules,
Journal Year:
2024,
Volume and Issue:
29(12), P. 2858 - 2858
Published: June 16, 2024
Endophytic
microorganisms
contribute
significantly
to
water
bioremediation
by
enhancing
pollutant
degradation
and
supporting
aquatic
plant
health
resilience
releasing
bioactive
compounds
enzymes.
These
inhabit
tissues
without
causing
disease
or
any
noticeable
symptoms.
Endophytes
effectively
aid
in
eliminating
contaminants
from
systems.
Nanoparticles
serve
as
potent
enhancers
processes,
augmenting
the
efficiency
of
increasing
surface
area
bioavailability,
thereby
improving
efficacy
rate
remediation.
Their
controlled
nutrient
release
ability
stabilize
endophytic
colonization
further
enhanced
sustainable
elimination
contaminated
environments.
The
synergistic
effect
endophytes
nanoparticles
remediation
has
been
widely
explored
recent
studies,
revealing
compelling
outcomes.
Water
pollution
poses
significant
threats
human
health,
ecosystems,
economies;
hence,
sixth
global
goal
Sustainable
Development
Agenda
2030
United
Nations
aims
ensure
availability
management
resources,
recognizing
their
crucial
importance
for
current
future
generations.
Conventional
methods
addressing
exhibit
several
limitations,
including
high
costs,
energy-intensive
production
hazardous
by-products,
insufficient
effectiveness
mitigating
emerging
pollutants
such
pharmaceuticals
microplastics.
Noticeably,
there
is
an
inability
remove
various
types
pollutants,
thus
resulting
incomplete
purification
cycles.
Nanoparticle-enhanced
offers
innovative,
eco-friendly
alternative
degrading
contaminants.
A
growing
body
research
shown
that
integrating
with
a
viable
alternative.
This
review
examines
potential
using
enhance
remediation,
exploring
combined
effects
applications
purification.
paper
also
provides
overview
synthetic
producing
endophyte–nanoparticle
composites
optimize
capabilities
aqueous
final
section
highlights
constraints
related
nanoparticles.
Journal of Marine Science and Engineering,
Journal Year:
2023,
Volume and Issue:
11(5), P. 1076 - 1076
Published: May 19, 2023
Environmental
emergency
awareness
has
been
gaining
momentum
in
recent
years
the
composite
manufacturing
industry,
with
a
new
generation
of
materials
minimizing
their
harmful
environmental
impacts
by
employing
more
sustainable
processes
and,
where
possible,
replacing
synthetic
bio-based
materials,
thus
efficiently
using
energy
and
material
resources.
In
this
context,
natural
fiber
composites
are
proposed
as
appealing
candidates
to
replace
or
reduce
use
fibers
for
reinforcing
polymers
several
industrial
fields,
such
marine
sector,
usage
extensively
studied
years.
This
review
aims
present
thorough
overview
applications,
discussing
most
relevant
criteria
required
applications
water
exposure
is
expected.
For
purpose,
outlines
matrices
used,
analyzes
resultant
composites’
mechanical
properties,
presents
treatments
before
manufacturing,
well
main
adopted
production.
The
advantages
disadvantages
compared
also
presented,
including
economic
credentials.
Finally,
list
components
reinforcements
developed
reported.
International Journal of Environmental Research and Public Health,
Journal Year:
2023,
Volume and Issue:
20(17), P. 6667 - 6667
Published: Aug. 28, 2023
Plastics,
due
to
their
varied
properties,
find
use
in
different
sectors
such
as
agriculture,
packaging,
pharmaceuticals,
textiles,
and
construction,
mention
a
few.
Excessive
of
plastics
results
lot
plastic
waste
buildup.
Poorly
managed
(as
shown
by
heaps
on
dumpsites,
free
spaces,
along
roads,
marine
systems)
the
landfills,
are
just
fraction
environment.
A
complete
picture
should
include
micro
nano-plastics
(MNPs)
hydrosphere,
biosphere,
lithosphere,
atmosphere,
current
extreme
weather
conditions
(which
effects
climate
change),
wear
tear,
other
factors
promote
MNP
formation.
MNPs
pose
threat
environment
more
than
pristine
counterparts.
This
review
highlights
entry
occurrence
primary
secondary
soil,
water
air,
together
with
aging.
Furthermore,
uptake
internalization,
plants,
animals,
humans
discussed,
toxicity
effects.
Finally,
future
perspective
conclusion
given.
The
material
utilized
this
work
was
acquired
from
published
articles
internet
using
keywords
waste,
degradation,
microplastic,
aging,
toxicity.
PeerJ,
Journal Year:
2024,
Volume and Issue:
12, P. e17807 - e17807
Published: Sept. 30, 2024
In
recent
years,
advances
in
nanotechnology
have
significantly
influenced
electronics
manufacturing,
industrial
processes,
and
medical
research.
Various
industries
seen
a
surge
the
use
of
nanomaterials.
However,
several
researchers
raised
alarm
about
toxicological
nature
nanomaterials,
which
appear
to
be
quite
different
from
their
crude
forms.
This
altered
can
attributed
unique
physicochemical
profile.
They
adversely
affect
human
health
environment.
Nanomaterials
that
been
released
into
environment
tend
accumulate
over
time
cause
significant
impact
on
ecosystem
organisms
with
adverse
effects.
Increased
nanoparticles
has
led
increased
exposure
daily
lives,
making
them
more
vulnerable
nanoparticle
toxicity.
Because
small
size,
nanomaterials
readily
cross
biological
membranes
enter
cells,
tissues,
organs.
Therefore,
effect
is
particular
concern.
The
effects
mechanisms
action
are
being
researched
worldwide.
Technological
also
support
monitoring
new
marketed
for
household
purposes.
It
challenging
area
because
exceptional
properties
updated
review
focuses
diverse
perspective
We
discussed
types
physiochemical
responsible
toxicity,
routes
exposure,
bio-distribution,
mechanism
includes
various
Critical Reviews in Environmental Science and Technology,
Journal Year:
2024,
Volume and Issue:
54(16), P. 1218 - 1235
Published: Jan. 19, 2024
Silver
nanoparticles
(AgNPs)
have
extensive
applications
in
nanomedicine
and
parasitology,
particularly
as
antifungal,
bactericidal,
antiviral,
larvicidal,
mosquitocidal,
tick-killing
agents.
Plant-based
AgNPs
(PB-AgNPs)
been
studied
a
safer
biocompatible
strategy
to
collaborate
disease
control.
However,
knowledge
concerning
the
toxicity
of
PB-AgNPs
non-target
organisms
is
still
limited.
A
scientometric
systematic
review
was
conducted
comprehensively
understand
potential
associated
with
these
nanoparticles.
In
brief,
assessment
toxicological
ecotoxicity
aspects
needs
be
aligned
their
development
for
target
organisms.
Our
demonstrates
that
different
can
cause
lethal
sublethal
effects
like
increased
oxidative
stress,
cardiotoxicity,
neurotoxicity,
hepatotoxicity,
hematotoxicity,
and,
DNA
damage,
alongside
others,
aquatic
Besides,
terrestrial
some
remains
poorly
understood.
Additionally,
similar
LC50
range
between
highlights
ecological
impact
PB-AgNPs.
Comprehensive
assessments
further
research
are
crucial
ensure
safe
sustainable
use
One
Health
context.
Journal of Hazardous Materials,
Journal Year:
2023,
Volume and Issue:
458, P. 131915 - 131915
Published: June 23, 2023
The
extensive
use
of
nanomaterials,
including
titanium
dioxide
nanoparticles
(TiO2
NPs),
raises
concerns
about
their
persistence
in
ecosystems.
Protecting
aquatic
ecosystems
and
ensuring
healthy
safe
aquaculture
products
requires
the
assessment
potential
impacts
NPs
on
organisms.
Here,
we
study
effects
a
sublethal
concentration
citrate-coated
TiO2
two
different
primary
sizes
over
time
flatfish
turbot,
Scophthalmus
maximus
(Linnaeus,
1758).
Bioaccumulation,
histology
gene
expression
were
assessed
liver
to
address
morphophysiological
responses
NPs.
Our
analyses
demonstrated
variable
abundance
lipid
droplets
(LDs)
hepatocytes
dependent
size,
an
increase
turbot
exposed
smaller
depletion
with
larger
patterns
genes
related
oxidative
immune
metabolism
(nrf2,
nfκb1,
cpt1a)
presence
exposure
supporting
variance
hepatic
LDs
distribution
citrate
coating
is
proposed
as
likely
catalyst
for
such
effects.
Thus,
our
findings
highlight
need
scrutinize
risks
associated
distinct
properties,
coatings,
crystalline
forms,
