| 4964 |
32 |
Au2Pt |
synergistic chemodynamic therapy / phototherapy |
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|
| 4972 |
39 |
Au@Rh‐ICG‐CM |
Alleviate Tumor Hypoxia for Simultaneous Bimodal Imaging and Enhanced Photodynamic Therapy |
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|
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|
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|
| 5063 |
158 |
AgPd@BSA/DOX |
Ag/Pd bimetal nanozyme with enhanced catalytic and photothermal effects for ROS/hyperthermia/chemotherapy triple-modality antitumor therap |
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|
| 5064 |
159 |
Au@Pt |
Au@Pt nanozymes were introduced to develop a low-cost, rapid, visual and highly sensitive immunochromatographic assay for streptomycin detection |
streptomycin |
Color |
|
|
0.06 |
ng/ml |
|
|
| 5065 |
159 |
Au@Pt |
Au@Pt nanozymes were introduced to develop a low-cost, rapid, visual and highly sensitive immunochromatographic assay for streptomycin detection |
streptomycin |
Color |
|
|
0.06 |
ng/ml |
|
The qualitative LOD was 0.1 ng mL−1 by the naked eye, and the quantitative LOD was 0.06 ng mL−1. |
| 5085 |
178 |
Au 1 Pd 5 |
A colorimetric test is developed for quantitative determination of acid phosphatase. |
Acid phosphatase (ACP) |
Color |
1-14 |
U/L |
0.53 |
U/L |
102% 103% 99% |
|
| 5086 |
178 |
Au 1 Pd 5 |
A colorimetric test is developed for quantitative determination of acid phosphatase. |
Acid phosphatase (ACP) |
Color |
1-14 |
U/L |
0.53 |
U/L |
102% 103% 99% |
To validate the application of this method in human serum, spiked-recovery experiments were carried out with different concentration of ACP. To fit the linear range of the established calibration plot, commercial human serum was appropriately diluted before addition of ACP. The recovery rates are 102 % for 4 U/L, 103 % for 8 U/L and 99 % for 12 U/L ACP (listed in Table 1). The good recovery results guarantee the reliability of this method for estimating ACP activity in biological fluid. |
| 5144 |
232 |
AuPtRu |
biothiol detection |
Biothiol |
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|
|
|
|
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|
| 5145 |
234 |
CdCo2O4 |
colorimetric detection of glucose |
glucose |
Color |
0.5-100 |
μM |
0.13 |
μM |
|
|
| 5204 |
312 |
PtRu NPs |
detection of Fe2+ and protection of Monascus pigments |
Fe2+ |
Color |
0.2-6.0 |
mM |
0.05 |
μM |
|
|
| 5293 |
385 |
Au@Pt nanoparticles |
a signal amplification strategy |
a widespread and dangerous phytopathogenic bacteria species (Clavibacter michiganensis) |
|
|
|
|
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|
| 5299 |
389 |
Au@PtNP |
Although these methods demonstrated advantages such as low cost and high selectiveness, the sensitivity needed to be improved further. In this work, we combined this Pb2+-S2O3 2−-based metal leaching with Au@PtNP nanozyme together to fabricate a new colorimetric determination of Pb2+. |
pb2+ |
Color |
20~800 |
nM |
3.0 |
nM |
|
|
| 5308 |
397 |
PtNi nanocubes |
Herein, based on PtNi NCs-catalyzed TSA strategy, an enzyme-free and ultrasensitive ECL cytosensor for the detection of HepG2 cells (as a model) was constructed. |
tyramine-luminol |
Fluor |
10~100000 |
cells/ml |
3 |
cells/ml |
|
|
| 5387 |
461 |
PdCuAu NPs |
detect glucose |
glucose |
Color |
0.5–500 |
μM |
25 |
nM |
|
|
| 5386 |
461 |
PdCuAu NPs |
detection of H2O2 |
H2O2 |
Color |
0.1–300 |
μM |
5 |
nM |
|
|
| 5449 |
505 |
PtCu NAs |
Prevention of pathologic α-synuclein transmission in Parkinson’s disease |
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|
| 5451 |
507 |
PtCu bimetallic nanoalloys (NAs) |
S for prevention of pathologic -synuclein transmission in Parkinson’s disease |
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|
| 5480 |
536 |
Cu/Au/Pt TNs |
Detection of microcystin-LR |
microcystin-LR |
Color |
4.0-10000 |
ng/L |
3.0 |
ng/L |
|
|
| 5494 |
554 |
Pd@Au nanostructures |
Detection of glucose |
glucose |
Color |
0.02-2 |
mM |
9.28 |
μM |
|
|
| 5500 |
560 |
Mesoporous Pd@Pt |
detection of atrazine |
atrazine |
Color |
0.1-500 |
ng/mL |
0.5 |
ng/mL |
98.6-103.3 |
|
| 5503 |
565 |
Au–Ag@HA NPs |
Enhanced Cancer Therapy |
|
|
|
|
|
|
|
|
| 5557 |
621 |
Au@Pt |
Ag+ detection by LSPR spectroscopy |
Ag+ |
Color |
0.5-1000 |
μM |
500 |
nM |
|
|
| 5566 |
629 |
DNA-Au/Pt NCs |
Detection of Staphylococcus aureus bacteria |
|
Color |
102-108 |
CFU/mL |
80 |
CFU/mL |
|
|
| 5570 |
637 |
Magnetite@cellulose NCs |
Glucose monitoring |
Glucose |
|
|
|
5 |
mM |
|
|
| 5658 |
735 |
Au@Pt |
highly sensitive sensing of matrix metalloproteinase 2 |
MMP-2 |
E-chem |
0.5–100 |
ng/mL |
0.18 |
ng/mL |
96.1 to 104.4% |
|
| 5667 |
744 |
Pt-GNRs |
cancer treatment |
|
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|
| 5678 |
752 |
Au@Pt |
The developed approach was used for reaching a lower limit of detection (LOD) and eliminating the background for the lateral flow immunoassay (LFIA) of the important plant pathogen potato virus X (PVX) in leaf and tuber extracts. |
|
|
|
|
31 |
pg/ml |
|
|
| 5687 |
758 |
Ag1Pd1 |
determine the concentration of I- ions in aqueous solution. |
iodide ions |
|
0.5-180 |
nM |
1.5 |
nM |
95.8%-99.9% |
As listed in Table 2, the recovery rates were calculated to be 99.9% for 30 nM, 95.8% for 80 nM and 99.0% for 120 nM spiked I− ions in cooking salt. For diluted human serum, the recovery rates were determined to be 92.4% for 25 nM, 107.0% for 50 nM, 102.8% for 75 nM, and 92.2% for 100 nM I− (Table 3). |
| 5724 |
798 |
PtPdCu TNAs |
Detection of Fe2+ and Evaluation of Antioxidant Capability |
Fe2+ |
Color |
0.01-0.20 |
mM |
0.005 |
mM |
|
|
| 5756 |
830 |
CA@PtNi hNS |
Sensitive detection of HSA |
HAS |
Color |
0–400 |
ng mL−1 |
0.19 |
ng mL−1 |
112-113% |
|
| 5848 |
938 |
PtPd NPs |
quantitative detection of lipocalin-2 |
lipocalin-2 |
conductometric |
0.01-30 |
ng/mL |
0.0059 |
ng/mL |
|
|
| 5853 |
944 |
Au@PtRu nanorods |
quantitative detection of alcohol |
alcohol |
Colorimetric |
0.25-4 |
mM |
23.8 |
μM |
|
|
| 5897 |
990 |
Pd1Cux NAFs |
Detection of H2O2 and Glucose |
Glucose |
Color |
10-500 |
μM |
2.93 |
μM |
|
|
| 5898 |
991 |
CA@PtRu ANPs |
Detection of C-reactive protein |
CRP |
Color |
0.01-180 |
μg |
0.01 |
μg |
97-109% |
|
| 5905 |
998 |
CoSe2 |
determination of D-penicillamine |
|
|
|
|
|
|
|
No Significant loss in peroxidase like activity even after 365 days. |
| 5961 |
1053 |
Au–Cu |
detection of H2O2 |
H2O2 |
Color |
1-10 |
μM |
0.141 |
μM |
|
|
| 5962 |
1053 |
Au–Cu |
detection of glucose |
glucose |
Color |
2-10 |
μM |
0.26 |
μM |
|
|
| 6038 |
1135 |
Ni–Pt NPs |
colorimetric immunoassay of carcinoembryonic antigen |
carcinoembryonic antigen (CEA) |
Color |
5-500 |
pg/mL |
1.1 |
pg/mL |
|
|
| 6050 |
1155 |
Au25, Au24Cu1 and Au24Cd1 |
modulation of neuroinflammation |
|
|
|
|
|
|
|
|
| 6060 |
1166 |
Pt–Ir NCs |
amplified lateral flow immunoassay for dehydroepiandrosterone |
dehydroepiandrosterone |
Unsure |
0.5-1000 |
ng/mL |
0.43 |
ng/mL |
90.8%-110.4% |
method: immunoassay |
| 6094 |
1210 |
Cr/CeO2 |
Cr/CeO2
nanozyme can improve the survival rate of LPS induced neuron cells via decreasing excessive RONS. The
in vivo experiments show the Cr/CeO2 nanozyme can promote wound healing and reduce
neuroinflammation of mice following brain trauma. The catalytic patch based on nanozyme provides a
noninvasive topical treatment route for TBI as well as other traumas diseases. |
|
|
|
|
|
|
|
|
| 6108 |
1233 |
Au-Pt |
SERS assay for glyphosate detection |
glyphosate |
SERS |
0.01-1000 |
mg/L |
0.005 |
mg/L |
|
|
| 6156 |
1303 |
Au@Pt NRs |
Detection of Ascorbic Acid |
|
Color |
|
|
|
|
|
|
| 6160 |
1307 |
Pt-Ni-Cu nanocube |
Detection of Gram-positive bacteria |
Gram-positive bacteria |
E-chem |
150-1.5*10^8 |
CFU/mL |
42 |
CFU/mL |
|
|
| 6203 |
1352 |
Cu(I)1.28Cu(II)0.36Se nanoparticles |
for Recognition, Enrichment, and Sensing of Mercury Ions |
Mercury Ions |
Color |
0-200 |
ppb |
4.55 |
ppb |
|
|
| 6274 |
1424 |
MoS2-Au@Pt |
Detection of Cys |
cysteine |
|
4.8-38.4 |
μM |
0.7 |
μM |
|
|
| 6280 |
1430 |
Pd-Pt |
Detection of Ascorbic acid |
Ascorbic acid (AA) |
Color |
1–15 |
μM |
0.40 |
μM |
|
|