Journal of Plant Nutrition and Soil Science,
Год журнала:
2023,
Номер
187(5), С. 565 - 588
Опубликована: Ноя. 21, 2023
Abstract
Iron
(Fe)
is
necessary
for
plant
growth
and
development.
deficiency
disrupts
major
metabolic
cellular
activities
such
as
respiration,
DNA
synthesis,
chlorophyll
synthesis.
also
activates
various
pathways
vital
to
numerous
enzymes.
widely
distributed
in
soil,
but
plants
do
not
readily
absorb
it.
In
addition
neutral
pH,
Fe
forms
insoluble
complexes
under
alkaline
conditions.
The
fundamental
cause
of
chlorosis
an
imbalance
between
the
solubility
soil
demand
by
plants.
Various
fertilizers,
including
organic,
chelated,
inorganic,
are
administered
leaves
treat
chlorosis.
Currently,
used
fertilizers
expensive,
easily
adsorb
on
particles,
leach
out
with
water,
thereby
diminishing
their
efficiency.
They
need
be
applied
repeatedly,
resulting
excessive
fertilizer
concentration
that
can
harm
usage
nanofertilizers
agricultural
production
has
expanded
address
disadvantages
existing
fertilizers.
advantages
nanosized
include
physical
chemical
characteristics,
high
surface
area
volume
ratio
aids
easy
absorption
plants’
roots
leaves.
Controlled‐release
iron
oxide
supply
regulated
release
nutrients
a
way
coordinated
nutritional
needs
crops.
This
improves
accumulation
plant,
filling
gap
nutrient
lowering
environmental
risks
due
leaching.
possibility
nanoparticles
micronutrient
uptake
mechanism
action,
advantages,
limitations
critically
highlighted
this
review
article.
Journal of Nanobiotechnology,
Год журнала:
2024,
Номер
22(1)
Опубликована: Март 5, 2024
Abstract
The
primary
factors
that
restrict
agricultural
productivity
and
jeopardize
human
food
safety
are
heavy
metals
(HMs),
including
arsenic,
cadmium,
lead,
aluminum,
which
adversely
impact
crop
yields
quality.
Plants,
in
their
adaptability,
proactively
engage
a
multitude
of
intricate
processes
to
counteract
the
impacts
HM
toxicity.
These
orchestrate
profound
transformations
at
biomolecular
levels,
showing
plant’s
ability
adapt
thrive
adversity.
In
past
few
decades,
stress
tolerance
crops
has
been
successfully
addressed
through
combination
traditional
breeding
techniques,
cutting-edge
genetic
engineering
methods,
strategic
implementation
marker-dependent
approaches.
Given
remarkable
progress
achieved
this
domain,
it
become
imperative
adopt
integrated
methods
mitigate
potential
risks
arising
from
environmental
contamination
on
yields,
is
crucial
as
we
endeavor
forge
ahead
with
establishment
enduring
systems.
manner,
nanotechnology
emerged
viable
field
sciences.
applications
extensive,
encompassing
regulation
stressors
like
toxic
metals,
improving
efficiency
nutrient
consumption
alleviating
climate
change
effects.
Integrating
nanomaterials
agrochemicals
mitigated
drawbacks
associated
agrochemicals,
challenges
organic
solvent
pollution,
susceptibility
photolysis,
restricted
bioavailability.
Numerous
studies
clearly
show
immense
nanofertilizers
tackling
acute
crisis
toxicity
production.
This
review
seeks
delve
into
using
NPs
effectively
enhance
resilience,
thereby
fostering
an
environmentally
friendly
economically
approach
toward
sustainable
advancement
foreseeable
future.
Plant and Soil,
Год журнала:
2024,
Номер
503(1-2), С. 313 - 330
Опубликована: Март 12, 2024
Abstract
Background
As
the
world
grapples
with
increasing
agricultural
demands
and
unpredictable
environmental
stressors,
there
is
a
pressing
need
to
improve
plant
resilience.
Therefore,
understanding
pioneering
role
of
nanoparticles
in
alleviating
stress
crucial
for
developing
stress-resilient
varieties
enhance
food
secure
world.
Nanoparticles
have
unique
physical
chemical
properties,
demonstrate
their
potential
growth,
nutrient
utilization,
tolerance.
This
review
delves
into
mechanistic
insights
nanoparticle-plant
interactions,
highlighting
how
these
tiny
particles
can
mitigate
diverse
stressors
such
as
drought,
salinity,
heavy
metal
toxicity.
The
action
different
types
nanoparticles,
including
metal,
carbon-based,
biogenic
are
discussed
context
interaction
physiology
responses.
Aims
article
also
explores
drawbacks
implications
nanoparticle
use,
emphasizing
responsible
sustainable
applications.
this
study
aimed
offer
exciting
possibilities
managing
both
biotic
abiotic
species,
from
improving
water-use
efficiency
resilience
via
nanotechnology.
Conclusions
Future
research
directions
suggested,
focusing
on
nano-bioengineering
precision
agriculture
create
crops
security.
Through
lens
interdisciplinary
research,
paper
underscores
significance
innovative
tools
realm
agriculture,
catalyzing
paradigm
shift
towards
farming
systems.
SVOA Microbiology,
Год журнала:
2024,
Номер
5(1), С. 01 - 14
Опубликована: Янв. 2, 2024
As
eco-friendly
alternative
to
chemical
fertilizers,
biofertilizers
have
gained
significance
in
the
quest
for
sustainable
farming.
While
challenges
exist,
such
as
regulatory
hurdles
and
technical
complexities,
opportunities
this
field
are
substantial.
Understanding
rhizosphere
engineering
can
enhance
biofertilizers'
efficiency,
ensuring
they
provide
maximum
crop
benefits.
Genetic
of
bioinoculants
offers
a
pathway
tailor
specific
needs,
potentially
increasing
their
effectiveness.
Multi-trait,
multi-strain,
multi-nutrient
microbial
formulations
potential
revolutionize
biofertilizer
market,
allowing
customized
solutions
that
address
range
agricultural
needs.
These
innovations
complemented
by
market
dynamics
integration
nanotechnology,
which
further
performance
reach.
Such
indicate
bright
future
commercialization,
where
agriculture
benefit
from
advanced
with
an
improved
understanding
soil-plant
interactions.
Biofertilizers'
prospects
promising,
offering
more
environmentally
friendly
approach
nourishing
world's
growing
population.
