Analytical Chemistry,
Год журнала:
2024,
Номер
96(33), С. 13663 - 13671
Опубликована: Авг. 10, 2024
Rapid
and
accurate
detection
of
human
epidermal
growth
factor
receptor
2
(HER2)
is
crucial
for
the
early
diagnosis
prognosis
breast
cancer.
In
this
study,
we
reported
an
iron-manganese
ion
N-doped
carbon
single-atom
catalyst
(FeMn-NC
Journal of the American Chemical Society,
Год журнала:
2024,
Номер
146(14), С. 10023 - 10031
Опубликована: Март 30, 2024
Single-atom
nanozyme-based
catalytic
therapy
is
of
great
interest
in
the
field
tumor
therapy;
however,
their
development
suffers
from
low
affinity
nanozymes
to
substrates
(H2O2
or
O2),
leading
deficient
activity
microenvironment.
Herein,
we
report
a
new
strategy
for
precisely
tuning
d-band
center
dual-atomic
sites
enhance
metal
atomic
and
on
class
edge-rich
N-doped
porous
carbon
Fe–Mn
(Fe1Mn1–NCe)
greatly
boosting
multiple-enzyme-like
activities.
The
as-made
Fe1Mn1–NCe
achieved
much
higher
efficiency
(Kcat/Km
=
4.01
×
105
S–1·M–1)
than
Fe1–NCe
2.41
104
with
an
outstanding
stability
over
90%
retention
after
1
year,
which
best
among
reported
dual-atom
nanozymes.
Theoretical
calculations
reveal
that
synergetic
effect
Mn
upshifts
Fe
−1.113
−0.564
eV
enhances
adsorption
capacity
substrate,
thus
accelerating
dissociation
H2O2
weakening
O–O
bond
O2.
We
further
demonstrated
superior
enzyme-like
combined
photothermal
could
effectively
inhibit
growth
vivo,
inhibition
rate
up
95.74%,
highest
value
artificial
enzyme
therapies
so
far.
Angewandte Chemie International Edition,
Год журнала:
2024,
Номер
63(18)
Опубликована: Фев. 23, 2024
Abstract
Single‐atom
nanozyme
(SAzyme)
has
sparked
increasing
interest
for
catalytic
antitumor
treatment
due
to
their
more
tunable
and
diverse
active
sites
than
natural
metalloenzymes
in
complex
physiological
conditions.
However,
it
is
usually
a
hard
task
precisely
conduct
catalysis
at
tumor
after
intravenous
injection
of
those
SAzyme
with
high
reactivity.
Moreover,
the
explorations
SAzymes
anticancer
application
are
still
its
infancy
need
be
developed.
Herein,
an
situ
synthesis
strategy
Cu
was
constructed
convert
adsorbed
copper
ions
into
isolated
atoms
anchored
by
oxygen
(Cu−O
2
/Cu−O
4
)
via
GSH‐responsive
deformability
supports.
Our
results
suggest
that
activation
process
could
further
facilitate
dissociation
consumption
glutathione,
thereby
leading
deposition
cytoplasm
triggering
cuproptosis.
peroxidase‐like
activity
enabled
intracellular
reactive
species
production,
resulting
specifically
disturbance
metabolism
pathway.
Meanwhile,
exposed
glucose
transporter
(GLUT)
inhibitor
phloretin
(Ph)
can
block
glycose
uptake
boost
cuproptosis
efficacy.
Overall,
this
effectively
diminished
off‐target
effects
SACs‐induced
therapies
introduced
promising
paradigm
advancing
cuproptosis‐associated
therapies.
Angewandte Chemie International Edition,
Год журнала:
2024,
Номер
unknown
Опубликована: Ноя. 19, 2024
Abstract
The
global
crisis
of
bacterial
infections
is
exacerbated
by
the
escalating
threat
microbial
antibiotic
resistance.
Nanozymes
promise
to
provide
ingenious
solutions.
Here,
we
reported
a
homogeneous
catalytic
structure
Pt
nanoclusters
with
finely
tuned
metal–organic
framework
(ZIF‐8)
channel
structures
for
treatment
infected
wounds.
Catalytic
site
normalization
showed
that
active
aggregates
fine‐tuned
pore
modifications
had
capacity
14.903×10
5
min
−1
,
which
was
18.7
times
higher
than
particles
in
monodisperse
state
ZIF‐8
(0.793×10
).
In
situ
tests
revealed
change
from
homocleavage
heterocleavage
hydrogen
peroxide
at
interface
nanozyme
one
key
reasons
improvement
activity.
Density‐functional
theory
and
kinetic
simulations
reaction
jointly
determine
role
center
substrate
together.
Metabolomics
analysis
developed
nanozyme,
working
conjunction
reactive
oxygen
species,
could
effectively
block
energy
metabolic
pathways
within
bacteria,
leading
spontaneous
apoptosis
rupture.
This
pioneering
study
elucidates
new
ideas
regulation
artificial
enzyme
activity
provides
perspectives
development
efficient
substitutes.
Journal of the American Chemical Society,
Год журнала:
2024,
Номер
146(14), С. 9721 - 9727
Опубликована: Апрель 1, 2024
The
volumetric
density
of
the
metal
atomic
site
is
decisive
to
operating
efficiency
photosynthetic
nanoreactor,
yet
its
rational
design
and
synthesis
remain
a
grand
challenge.
Herein,
we
report
shell-regulating
approach
enhance
Co
sites
onto/into
multishell
ZnxCd1–xS
for
greatly
improving
CO2
photoreduction
activity.
We
first
establish
quantitative
relation
between
number
shell
layers,
specific
surface
areas,
on
conclude
positive
performance
layers.
triple-shell
ZnxCd1–xS–Co1
achieves
highest
CO
yield
rate
7629.7
μmol
g–1
h–1,
superior
those
double-shell
(5882.2
h–1)
single-shell
(4724.2
h–1).
Density
functional
theory
calculations
suggest
that
high-density
can
promote
mobility
photogenerated
electrons
adsorption
Co(bpy)32+
increase
activation
(CO2
→
CO2*
COOH*
CO*
CO)
via
S–Co-bpy
interaction,
thereby
enhancing
photocatalytic
reduction.
Analytical Chemistry,
Год журнала:
2024,
Номер
unknown
Опубликована: Сен. 10, 2024
Photoelectrochemical
(PEC)
sensing
mechanisms
based
on
enzyme-catalyzed
strategies
primarily
achieve
the
quantitative
analysis
of
biomolecules
through
enhancement
or
attenuation
photocurrent
signals.
However,
there
are
still
no
reports
that
delve
into
principles
signaling
conversion
in
reaction
between
photoactive
materials
and
biomolecules.
In
this
work,
we
demonstrated
indium
oxysulfide
InOS-0.5
heterojunction
has
excellent
peroxidase
activity
to
catalyze
H
Nano-Micro Letters,
Год журнала:
2024,
Номер
16(1)
Опубликована: Фев. 19, 2024
Dry
eye
disease
(DED)
is
a
major
ocular
pathology
worldwide,
causing
serious
discomfort
and
even
visual
impairment.
The
incidence
of
DED
gradually
increasing
with
the
high-frequency
use
electronic
products.
Although
inflammation
core
cause
vicious
cycle,
reactive
oxygen
species
(ROS)
play
pivotal
role
in
cycle
by
regulating
from
upstream.
Therefore,
current
therapies
merely
targeting
show
failure
treatment.
Here,
novel
dual-atom
nanozymes
(DAN)-based
drops
are
developed.
antioxidative
DAN
successfully
prepared
embedding
Fe
Mn
bimetallic
single-atoms
N-doped
carbon
material
modifying
it
hydrophilic
polymer.
vitro
vivo
results
demonstrate
endowed
superior
biological
activity
scavenging
excessive
ROS,
inhibiting
NLRP3
inflammasome
activation,
decreasing
proinflammatory
cytokines
expression,
suppressing
cell
apoptosis.
Consequently,
effectively
alleviate
inflammation,
promote
corneal
epithelial
repair,
recover
goblet
density
tear
secretion,
thus
breaking
cycle.
Our
findings
open
an
avenue
to
make
as
intervention
form
ROS-mediated
inflammatory
diseases.
Abstract
Modifying
the
coordination
or
local
environments
of
single‐,
di‐,
tri‐,
and
multi‐metal
atom
(SMA/DMA/TMA/MMA)‐based
materials
is
one
best
strategies
for
increasing
catalytic
activities,
selectivity,
long‐term
durability
these
materials.
Advanced
sheet
supported
by
metal
atom‐based
have
become
a
critical
topic
in
fields
renewable
energy
conversion
systems,
storage
devices,
sensors,
biomedicine
owing
to
maximum
utilization
efficiency,
precisely
located
centers,
specific
electron
configurations,
unique
reactivity,
precise
chemical
tunability.
Several
offer
excellent
support
are
attractive
applications
energy,
medical
research,
such
as
oxygen
reduction,
production,
hydrogen
generation,
fuel
selective
detection,
enzymatic
reactions.
The
strong
metal–metal
metal–carbon
with
metal–heteroatom
(i.e.,
N,
S,
P,
B,
O)
bonds
stabilize
optimize
electronic
structures
atoms
due
interfacial
interactions,
yielding
activities.
These
provide
models
understanding
fundamental
problems
multistep
This
review
summarizes
substrate
structure‐activity
relationship
different
active
sites
based
on
experimental
theoretical
data.
Additionally,
new
synthesis
procedures,
physicochemical
characterizations,
biomedical
discussed.
Finally,
remaining
challenges
developing
efficient
SMA/DMA/TMA/MMA‐based
presented.
