Environmental Science & Technology,
Год журнала:
2024,
Номер
58(32), С. 14078 - 14087
Опубликована: Авг. 2, 2024
In
situ
contaminant
degradation
and
detoxification
mediated
by
microbes
minerals
is
an
important
element
of
green
remediation.
Improved
understanding
microbe-mineral
interactions
on
the
nanoscale
offers
promising
opportunities
to
further
minimize
environmental
energy
footprints
site
this
Perspective,
we
describe
new
methodologies
that
take
advantage
array
multidisciplinary
tools─including
multiomics-based
analysis,
bioinformatics,
machine
learning,
gene
editing,
real-time
spectroscopic
microscopic
computational
simulations─to
identify
key
microbial
drivers
in
real
environments,
characterize
dynamic
interplay
between
with
high
spatiotemporal
resolutions.
We
then
reflect
how
knowledge
gained
can
be
exploited
modulate
binding,
electron
transfer,
metabolic
activities
at
interfaces,
develop
detoxication
technologies
combined
merits
efficacy,
material
longevity,
low
impacts.
Two
main
strategies
are
proposed
maximize
synergy
microbes,
including
using
mineral
nanoparticles
enhance
versatility
microorganisms
(e.g.,
tolerance
stresses,
growth
metabolism,
directed
migration,
selectivity,
transfer),
synthesize
regenerate
highly
dispersed
nanostructures
desired
structural/surface
properties
reactivity.
Chemical Reviews,
Год журнала:
2024,
Номер
124(15), С. 9081 - 9112
Опубликована: Июнь 20, 2024
Nanomaterial-microorganism
hybrid
systems
(NMHSs),
integrating
semiconductor
nanomaterials
with
microorganisms,
present
a
promising
platform
for
broadband
solar
energy
harvesting,
high-efficiency
carbon
reduction,
and
sustainable
chemical
production.
While
studies
underscore
its
potential
in
diverse
solar-to-chemical
conversions,
prevailing
NMHSs
grapple
suboptimal
conversion
efficiency.
Such
limitations
stem
predominantly
from
an
insufficient
systematic
exploration
of
the
mechanisms
dictating
flow.
This
review
provides
overview
notable
advancements
this
nascent
field,
particular
focus
on
discussion
three
pivotal
steps
flow:
capture,
cross-membrane
transport,
into
chemicals.
key
challenges
faced
each
stage
are
independently
identified
discussed,
viable
solutions
correspondingly
postulated.
In
view
interplay
affecting
overall
efficiency
conversion,
subsequent
discussions
thus
take
integrative
viewpoint
to
comprehend,
analyze
improve
flow
current
different
configurations,
highlighting
contemporary
techniques
that
can
be
employed
investigate
various
aspects
within
NMHSs.
Finally,
concluding
section
summarizes
opportunities
future
research,
providing
roadmap
continued
development
optimization
Green Carbon,
Год журнала:
2024,
Номер
2(3), С. 322 - 336
Опубликована: Июнь 20, 2024
The
nanomaterial-biological
hybrid
system
(NBHS)
is
a
rapidly
growing
interdisciplinary
field
that
combines
photocatalytic
nanomaterials
with
biological
systems,
leveraging
the
superior
light-harvesting
capabilities
of
and
excellent
selectivity
enzymes
microbes.
This
integration
enables
conversion
solar
energy
into
chemical
products
high
efficiency,
attracting
significant
research
interest
from
fields
renewable
environmental
science.
Despite
notable
advances,
synergy
mechanisms
between
abiotic
biotic
enzymes/microbes
remain
unclear.
review
outlines
latest
progress
in
NBHS,
encompassing
material-enzyme
hybrids
material-microbial
hybrids,
explores
design
principles.
Specifically,
it
examines
crucial
role
electron
transfer
modes
enhancing
synergistic
efficiency
systems
by
analyzing
various
at
interface.
Drawing
existing
literature,
highlights
use
interfacial
coenzymes
cytochromes
to
elucidate
nano/bio-material
synergy.
fundamental
understanding
unveils
opportunities
enhance
biocompatible
interfaces
mechanisms,
enabling
non-photosensitive
bacteria
harness
for
light-driven
intracellular
metabolism
CO2
bio-reduction
value-added
chemicals.
By
offering
comprehensive
overview
this
also
lays
groundwork
development
more
powerful
aimed
achieving
carbon
neutrality.
Nature Communications,
Год журнала:
2024,
Номер
15(1)
Опубликована: Май 22, 2024
Abstract
Biotic-abiotic
hybrid
photocatalytic
system
is
an
innovative
strategy
to
capture
solar
energy.
Diversifying
energy
conversion
products
and
balancing
photoelectron
generation
transduction
are
critical
unravel
the
potential
of
photocatalysis.
Here,
we
harvest
in
a
dual
mode
for
Cu
2-x
Se
nanoparticles
biomineralization
seawater
desalination
by
integrating
merits
Shewanella
oneidensis
MR-1
biogenic
nanoparticles.
Photoelectrons
generated
extracellular
0
power
synthesis
through
two
pathways
that
either
cross
outer
membrane
activate
periplasmic
Cu(II)
reduction
or
directly
delivered
into
space
Cu(I)
evolution.
Meanwhile,
photoelectrons
drive
reversing
MtrABC
complexes
S.
.
Moreover,
unique
photothermal
feature
as-prepared
nanoparticles,
natural
hydrophilicity,
linking
properties
bacterium
offer
convenient
way
tailor
membranes
water
production.
This
study
provides
paradigm
source
sink
diversifying
biotic-abiotic
platforms.
Advanced Materials,
Год журнала:
2023,
Номер
unknown
Опубликована: Сен. 7, 2023
At
the
intersection
of
synthetic
biology
and
materials
science,
engineered
living
(ELMs)
exhibit
unprecedented
potential.
Possessing
unique
"living"
attributes,
ELMs
represent
a
significant
paradigm
shift
in
material
design,
showcasing
self-organization,
self-repair,
adaptability,
evolvability,
surpassing
conventional
materials.
This
review
focuses
on
reviewing
applications
derived
from
bacteria,
fungi,
plants
environmental
remediation,
eco-friendly
architecture,
sustainable
energy.
The
provides
comprehensive
overview
latest
research
progress
emerging
design
strategies
for
various
application
fields
perspectives
science.
In
addition,
valuable
references
novel
ELMs,
extending
potential
future
ELMs.
investigation
into
synergistic
possibilities
amongst
different
species
offers
beneficial
reference
information
researchers
practitioners
this
field.
Finally,
trends
development
challenges
coming
years
are
discussed
detail.
Accounts of Chemical Research,
Год журнала:
2024,
Номер
57(9), С. 1398 - 1410
Опубликована: Апрель 23, 2024
ConspectusElectrical
neuromodulation
has
achieved
significant
translational
advancements,
including
the
development
of
deep
brain
stimulators
for
managing
neural
disorders
and
vagus
nerve
seizure
treatment.
Optoelectronics,
in
contrast
to
wired
electrical
systems,
offers
leadless
feature
that
guides
multisite
high
spatiotemporal
system
targeting,
ensuring
specificity
precision
therapies
known
as
"photoelectroceuticals".
This
Account
provides
a
concise
overview
developments
novel
optoelectronic
nanomaterials
are
engineered
through
innovative
molecular,
chemical,
nanostructure
designs
facilitate
interfacing
with
efficiency
minimally
invasive
implantation.This
outlines
progress
made
both
within
our
laboratory
across
broader
scientific
community,
particular
attention
implications
materials
innovation
strategies,
studying
bioelectrical
activation
methods,
applications
regenerative
medicine.
In
innovation,
we
highlight
nongenetic,
biocompatible,
approach
spans
various
length
scales,
from
single
neurons
tissues
using
nanosized
particles
monolithic
membranes.
Furthermore,
discussion
exposes
critical
unresolved
questions
field,
mechanisms
interaction
at
nanobio
interface,
cellular
or
tissue
integration
into
existing
networks
modulation.
addition,
present
challenges
pressing
needs
long-term
stability
biocompatibility,
scalability
clinical
applications,
noninvasive
monitoring
control
systems.In
addressing
field
interfaces,
particularly
envisage
promising
strategic
directions
could
significantly
advance
this
burgeoning
domain.
involves
deeper
theoretical
understanding
nanobiointerfaces,
where
simulations
experimental
validations
on
how
interact
spatiotemporally
biological
systems
crucial.
The
more
durable
is
vital
prolonged
dynamic
ability
manipulate
activity
spatial
resolution,
paves
way
targeting
individual
specific
circuits.
Additionally,
integrating
these
interfaces
advanced
possibly
leveraging
artificial
intelligence
machine
learning
algorithms
programming
dynamically
responsive
designs,
ease
implementation
stimulation
recording.
These
innovations
hold
potential
introduce
treatment
modalities
wide
range
neurological
systemic
disorders.
Chemical Society Reviews,
Год журнала:
2024,
Номер
53(16), С. 8306 - 8378
Опубликована: Янв. 1, 2024
As
natural
living
substances,
microorganisms
have
emerged
as
useful
resources
in
medicine
for
creating
microbe-material
hybrids
ranging
from
nano
to
macro
dimensions.
The
engineering
of
microbe-involved
nanomedicine
capitalizes
on
the
distinctive
physiological
attributes
microbes,
particularly
their
intrinsic
"living"
properties
such
hypoxia
tendency
and
oxygen
production
capabilities.
Exploiting
these
remarkable
characteristics
combination
with
other
functional
materials
or
molecules
enables
synergistic
enhancements
that
hold
tremendous
promise
improved
drug
delivery,
site-specific
therapy,
enhanced
monitoring
treatment
outcomes,
presenting
substantial
opportunities
amplifying
efficacy
disease
treatments.
This
comprehensive
review
outlines
microbial
derivatives
used
biomedicine
specific
advantages
therapeutic
application.
In
addition,
we
delineate
fundamental
strategies
mechanisms
employed
constructing
hybrids.
diverse
biomedical
applications
constructed
hybrids,
encompassing
bioimaging,
anti-tumor,
anti-bacteria,
anti-inflammation
diseases
therapy
are
exhaustively
illustrated.
We
also
discuss
current
challenges
prospects
associated
clinical
translation
hybrid
platforms.
Therefore,
unique
versatility
potential
exhibited
by
position
them
promising
candidates
development
next-generation
biomaterials
theranostic
functionalities.
