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    • Enzyme-like Activity
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    • Peroxidase
    ref material application target method linear range linear range unit LOD LOD unit recovery comment
    4957 23 Co3O4@Co-Fe oxide double-shelled nanocages Detection H2O2 Color 0.02 - 600 μM 0.02 μM
    4956 23 Co3O4@Co-Fe oxide double-shelled nanocages Detection acetylcholinesterase (AChE) Color 0.0008-1 mU/mL 0.0002 mU/mL
    4959 27 Cu–N–C Detection organophosphorus pesticides Color 1-300 ng/mL 0.6 ng/mL
    4960 27 Cu–N–C Detection acetylcholine Color 10-8000 μM 1.24 μM
    4962 31 FeS2 NPs quantitative detection of H2O2 or GSH GSH Color 0.20-3.5 μM 0.15 μM
    4963 31 FeS2 NPs quantitative detection of H2O2 or GSH H2O2 Color 2-80 μM 0.91 μM
    4964 32 Au2Pt synergistic chemodynamic therapy / phototherapy
    4967 36 P-Co3O4 Detection of H2O2 and Glucose GSH Color 10-30 μM 0.69 μM
    4968 36 P-Co3O4 Detection of H2O2 and Glucose H2O2 Color 1-30 μM 0.77 μM
    4969 36 R-Co3O4 Detection of H2O2 and Glucose GSH Color 1-20 μM 0.32 μM
    4970 36 R-Co3O4 Detection of H2O2 and Glucose H2O2 Color 1-30 μM 0.43 μM
    4973 40 MoS2/g-C3N4 HNs sulfide ions sensing S2- Color 0.1-10 μM 37 μM
    4980 54 GOx@MOF-545(Fe) glucose Color 0.5–100 μM 0.28000000000000003 μM
    4983 61 Fe3O4-TiO2/rGO (FTG) detection and photodegradation of pesticide atrazine Color 2-20 μg/L 2.98 μg/L
    4985 64 NCNTs@MoS2 Detection of AA Ascorbic acid (AA) Color 0.2-80 μM 0.12 μM
    4986 64 NCNTs@MoS2 Detection of H2O2 H2O2 Color 2–50 μM 0.14 μM
    4988 68 Fe3O4@SiO2-NH2-Au@PdNPs Detection of Glucose glucose Color 0.010−60 μM 0.06 μM 0.93
    4990 73 vanadium oxide nanodots (VOxNDs) Antibacterial
    4994 78 AuNP-ICA platform Detection of Escherichia coli O157:H7 in Milk E. coli Color 5-2.5*10^5 CFU/mL 12.5 CFU/mL 90.94
    4995 82 PNCNzyme Activating IAA to produce abundant ROS and triggering tumor cell apo-ptosis
    4996 84 Co-V MMO nanowires Antibacterial
    4999 91 Au@AgPt detection Hg2+ SERS 1-10000 nM 0.28 nM
    5000 91 Au@AgPt detection Hg2+ Color 1-100 μM 0.52 μM
    5002 94 cNFs antimicrobial H2O2 Color
    5003 95 Co3O4 Detection of S. aureus S. aureus Color 10–10000 cfu/mL 8 cfu/mL
    5004 96 AuNCs detaction of tetracycline antibiotics tetracycline antibiotics Color 1-16 μM 46 nM
    5005 97 Prussian Blue detection of lactate lactate E-chem
    5006 98 Tb-OBBA-Hemin Detection and Degradation of Estrogen Endocrine Disruptors 17β-estradiol Fluor 0-100 nM 5 nM
    5010 106 IMSN-PEG-TI The results show that IMSN nanozyme exhibits both intrinsic peroxidase-like and catalase-like activities under acidic TME, which can decompose H2O2 into hydroxyl radicals (•OH) and oxygen (O2), respectively
    5011 108 HP-MIL-88B-BA exhibited a rapid response to glucose (10 min) glucose Color 2-100 μM 0.98 μM
    5012 109 IrOx demonstrate for the first time that iridium oxide nanoparticles (IrOx) possess acid-activated oxidase and peroxidase-like functions and wide pH-dependent catalase-like properties. Integrating of glucose oxidase (GOD) could unlock its oxidase and peroxidase activities by gluconic acid produced by catalysis of GOD towards glucose in cancer cells, and the produced H2O2 can be converted to O2 to compensate its consumption in GOD catalysis due to the catalase-like function of the nanozyme, which result in continual consumption of glucose and self-supplied substrates for generating superoxide anion and hydroxyl radical.
    5014 111 F-BS NCs virus-like F-BS NCs have been successfully constructed by simple ultrasound that possesses PA and IRT imaging capacity, by which synergetic PT and PT-enhanced nanozymatic biocatalytic cancer-combating therapy is hopeful to be realized.
    5023 121 CeO2/C nanowires glucose Color 1-100 μM 0.69 μM
    5029 128 BNS-CDs H2O2 Color 3-30 μM 0.8 μM 92.7-108.3% Smartphone colorimetric determination
    5030 129 CoFe-LDH/CeO2 glucose Color 0.05-2 mM 0.015 mM
    5031 129 CoFe-LDH/CeO2 H2O2 Color 0.01-1 mM 0.003 mM
    5035 137 Zr-MOF Quantification and discrimination of phosphorylated proteins α-casein Color 0.17-5 μg/mL 0.16 μg/mL
    5036 137 Zr-MOF Quantification and discrimination of phosphorylated proteins α-casein Color 0.17-5 μg/mL 0.16 μg/mL Further, the absorbance at 652 nm is linearly decreased with the increased levels of α-CS ranging from 0.17 to 5.0 μg/mL (Fig. 4B). The equation can be written as A = −0.0554[α-CS] (μg/mL) + 0.4119 (R2 = 0.996). The limit of detection (LOD) is calculated to be 0.16 μg/mL based on S/N = 3.
    5038 139 AuNFs/Fe3O4@ZIF-8-MoS2 Electrochemical detection of H2O2 released from cells H2O2 E-chem 5-15000 μM 0.9 μM
    5039 139 AuNFs/Fe3O4@ZIF-8-MoS2 Electrochemical detection of H2O2 released from cells H2O2 E-chem 15-120 mM 0.9 μM One was from 5 μM to 15 mM with a linear regression equation of I(μA) = 0.0171C(μM) + 16.6 (R2 = 0.990) (Fig. 4d), and the other was from 15 mM to 120 mM with a linear regression equation of I(μA) = 0.00417C(μM) + 191 (R2 = 0.993) (Fig. 4e). The reason for two linear regions was probably caused by the different H2O2 absorption and activation behavior on AuNFs/Fe3O4@ZIF-8-MoS2 hybrid catalyst under different H2O2 concentration [4].
    5041 141 CDAu detection of Pb(II) Pb(II) Color 0.0005–0.46 μM 0.25 nM
    5042 141 CDAu detection of Pb(II) Pb(II) Color 0.0005–0.46 μM 0.25 nM Thus, a new and highly sensitive synergetic catalytic fluorescence method for the determination of 0.0005–0.46 μmol/L Pb(II) was established, with a detection limit of 0.25 nmol/L,
    5044 144 Au21Pd79 glucose detection glucose Color 5-400 μM 0.85 μM
    5048 148 AgNP@CD Detection of H2O2 and Glucose Glucose Color 1-600 μM 10 nM
    5049 148 AgNP@CD Detection of H2O2 and Glucose H2O2 Color 0.01-9 μM 9 nM
    5051 150 Co3O4 NPs detection of L-Ascorbic acid L-Ascorbic acid Color 0.01-0.35 mM 3.91 μM
    5052 150 Co3O4@β-CD NPs detection of L-Ascorbic acid L-Ascorbic acid Color 0.01-0.6 mM 1.09 μM 96.8% - 113.0%
    5053 150 Co3O4@β-CD NPs detection of L-Ascorbic acid L-Ascorbic acid Color 0.01-0.6 mM 1.09 μM 96.8% - 113.0% Besides, in order to investigate the precision of Co3O4@β-CD NPs detection method, recovery experiments were made by adding a serious of AA solution with different concentration. As shown in Table S3, the average recovery of all the samples was range from 96.8% to 113.0%.
    5060 156 Au@NH2-MIL-125(Ti) Colorimetric detection of Hg2+ Hg2+ Color 1-5 μM 0.1 μM 104.1±3.03 104.1±3.03 at 3μM; 91.56±2.03 at 6μM; 106.9±2.53 μM
    5057 156 Au@NH2-MIL-125(Ti) Colorimetric detection of H2O2 and cysteine H2O2 Color 2–10 μM 0.24 μM
    5058 156 Au@NH2-MIL-125(Ti) Colorimetric detection of Hg2+ Hg2+ Color 1-5 μM 0.1 μM 104.1±3.03
    5059 156 Au@NH2-MIL-125(Ti) Colorimetric detection of Hg2+ cysteine Color 1–10 μM 0.14 μM 93.8±3.23
    5061 156 Au@NH2-MIL-125(Ti) Colorimetric detection of Hg2+ cysteine Color 1–10 μM 0.14 μM 93.8±3.23 93.8±3.23 at4.0 μM; 100.3 ±5.62 at 7.0 μM; 103.5±6.13 at 9.0 μM
    5062 157 PEG/Ce-Bi@DMSN in vitro photothermal-enhanced nanocatalytic therapeutic efficacy
    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.
    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
    5070 164 PBNPs in TiNM To use the POD-like activity of PBNPs in sensitive detection of telomerase, TMB, one of the well-studied substrates for evaluating POD activity, was used in our design telomerase Color 1 cell
    5072 165 VONP-LPs To determine the linear range and sensitivity of the developed dualmodality sensor, different concentrations of NoV-LPs are examined. Anti-NoV antibody-conjugated VONP-LPs, MNPs and aliquot of NoV-LPs with various concentrations are mixed. VONP-LPs and the MNPs are bound with NoV-LPs through the specific interaction with antibody on their surface and a nanoconjugate of VONP-LPs, NoV-LPs and MNPs is formed. NoV-LPs Color 10-108 fg/ml 4.1 fg/ml
    5071 165 VONP-LPs Above results confirmed the ultra sensitivity and excellent specificity of the VONP-LPs based dual-modality biosensor proving applicability of developed sensor for real samples (Fig. 5b). To confirm the practicability real clinical samples are examined. Different types of clinical NoV (GII. 2, GII. 3, GII.4) from human feces of infected patients are detected using the developed dual-modality sensor NoV-LPs and clinical samples Color 100-107 copies/ml 72 copies/ml
    5074 166 CB-CQDs The detection of biothiols was performed as follows: in a series of colorimetric tubes, 0.5 mL of TMB (20 mM), 0.5 mL of H2O2 (25 mM), and 0.1 mL of CB-CQDs were fully mixed in 3.8 mL of HAc-NaAc buffer at pH4.5. Then, various concentrations of biothiols standard solution (0.1 mL) were added into the above mixture. After they were well mixed and incubated at 40 °C for 25 min, the absorption spectra were recorded on a Unico 4802 ultraviolet-visible spectrophotometer at room temperature. The calibration curves for biothiols were established according to the decrease of absorbance defined as ΔA=A0﹣A, where A0 and A denote the absorbance at 652 nm without and with analyte, individually. cysteine Color 0.5-20 μM 0.4 μM 95.9±2.7
    5073 166 CB-CQDs The detection of biothiols was performed as follows: in a series of colorimetric tubes, 0.5 mL of TMB (20 mM), 0.5 mL of H2O2 (25 mM), and 0.1 mL of CB-CQDs were fully mixed in 3.8 mL of HAc-NaAc buffer at pH4.5. Then, various concentrations of biothiols standard solution (0.1 mL) were added into the above mixture. After they were well mixed and incubated at 40 °C for 25 min, the absorption spectra were recorded on a Unico 4802 ultraviolet-visible spectrophotometer at room temperature. The calibration curves for biothiols were established according to the decrease of absorbance defined as ΔA=A0﹣A, where A0 and A denote the absorbance at 652 nm without and with analyte, individually. cysteine Color 0.5-20 μM 0.4 μM 95.9±2.7 105.7±2.0; 109.3±1.1; 99.7±4.3; 91.5±1.0; 98.2±2.3
    5075 167 UsAuNPs/MOFs H2O2 is widely used in the treatment of bacterial infections. However, compared with H2O2, hydroxyl radicals are much more reactive and can cause more serious oxidative damages to bacteria.[37] Given the excellent POD-like activity of the prepared UsAuNPs/MOFs, the in vitro antimicrobial activities against Staphylococcus aureus and Escherichia coli were evaluated in the presence of H2O2.
    5078 168 MIL-101(Fe) According to the enzyme cascade amplification strategy, the MIL-101(Fe) nanozyme in conjunction with AChE and ChOx provided a novel label-free fluorescent assay for detection of choline and ACh with high selectivity and sensitivity. Given this, this proposed sensing strategy was successfully utilized to detect the choline in milk and ACh in human plasma with desirable results choline Fluor 0.05-10 μM 20 nM
    5076 168 MIL-101(Fe) According to the enzyme cascade amplification strategy, the MIL-101(Fe) nanozyme in conjunction with AChE and ChOx provided a novel label-free fluorescent assay for detection of choline and ACh with high selectivity and sensitivity. Given this, this proposed sensing strategy was successfully utilized to detect the choline in milk and ACh in human plasma with desirable results H2O2 Fluor 0.1-130 μM 1.1 nM
    5077 168 MIL-101(Fe) According to the enzyme cascade amplification strategy, the MIL-101(Fe) nanozyme in conjunction with AChE and ChOx provided a novel label-free fluorescent assay for detection of choline and ACh with high selectivity and sensitivity. Given this, this proposed sensing strategy was successfully utilized to detect the choline in milk and ACh in human plasma with desirable results Ach Fluor 0.1-100 μM 8.9 nM
    5081 172 Fe3O4@PDA@BSA-Bi2S3 a Fe3O4@PDA@BSA-Bi2S3 composite theranostic agent was successfully prepared for synergistic tumor PTT and CDT, in which the BSA coating endows the NPs with colloidal stability and both in vitro and in vivo biocompatibility.
    5083 174 IrRu-GOx@PEG NPs Iridium/ruthenium nanozyme reactors with cascade catalytic ability for synergistic oxidation therapy and starvation therapy in the treatment of breast cancer
    5084 175 Fe3O4/CoFe-LDH A sensitively and selectively visual sensor for the determination of ascorbic acid (AA) was successfully constructed based on the reduction effect of AA with enediol group on the formed oxidation of TMB Ascorbic acid (AA) Color 0.5-10 μM 0.2 μM 98.3%-101.3%
    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.
    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%
    5087 179 Pt@PMOF (Fe) H2O2 sensor without adding redox mediators
    5090 179 Pt@PMOF (Fe) H2O2 sensor without adding redox mediators When applied in electrocatalysis, due to the synergy between PMOF(Fe) and Pt NPs, the Pt@PMOF(Fe) modified electrode offers high activities toward to the reduction of H2O2, which could be used for H2O2 sensor without adding redox mediators.
    5089 179 Pt@PMOF (Fe) afford ORR in PBS Furthermore, the Pt NPs with porphyrin in PMOF(Fe) could afford ORR in PBS, which has the potential for fuel cells and biofuel cells, especially in cancer diagnosis.
    5088 179 Pt@PMOF (Fe) afford ORR in PBS
    5092 181 hemin@CD a colorimetric and fluorescent dual-channel sensor for H2O2, glucose and xanthine was developed, and the results are satisfied in the application of real samples xanthine Fluor 0.17–33 μM 0.12 μM 98.8-103.6%
    5091 181 hemin@CD a colorimetric and fluorescent dual-channel sensor for H2O2, glucose and xanthine was developed, and the results are satisfied in the application of real samples glucose Fluor 0.17–133 μM 0.15 μM 92.2%~105.6%
    5093 181 hemin@CD a colorimetric and fluorescent dual-channel sensor for H2O2, glucose and xanthine was developed, and the results are satisfied in the application of real samples xanthine Color 0.17–33 μM 0.15 μM 93.4-102.4%
    5094 181 hemin@CD a colorimetric and fluorescent dual-channel sensor for H2O2, glucose and xanthine was developed, and the results are satisfied in the application of real samples H2O2 Fluor 0.17–133 μM 0.15 μM
    5095 181 hemin@CD a colorimetric and fluorescent dual-channel sensor for H2O2, glucose and xanthine was developed, and the results are satisfied in the application of real samples glucose Color 0.17–133 μM 0.15 μM 92.2%~105.6%
    5096 181 hemin@CD a colorimetric and fluorescent dual-channel sensor for H2O2, glucose and xanthine was developed, and the results are satisfied in the application of real samples H2O2 Color 0.17–133 μM 0.11 μM
    5102 186 mGPB a multi-enzyme system (mGPB) with self-sufficient H2O2 supply and photoselective multienzyme-like activities was developed for enhanced tumor catalytic therapy
    5103 189 CC-PdNPs detection of iodine ions iodine ions Color 0-6.25 Nm 0.19 nM 95.52-102.8%
    5108 198 TPyP-CuS ascorbic acid (AA) Ascorbic acid (AA) Color 1-30 μM 0.419 μM
    5107 198 TPyP-CuS detect H2O2 H2O2 Color 1.0-8.0 mM 121.8 μM
    5110 200 GeO2 Colorimetric Assay of OPs paraoxon Color 0.1-50 pM 14 fM Typically, 100 µL of different concentrations of paraoxon (0, 0.1, 2, 5, 10, 15, 30, 50, 70, 100 pm) were mixed with 20 µL of PB solutions (0.1 m, pH 8.0) containing AChE (10 µg mL−1). After the incubation for 20 min at 37 °C, 20 µL of ATCh solution (10 mm) and 20 µL of GeO2 nanozymes solution (1 mg mL−1) were added into the above mixture respectively for another 20 min incubation. The residual GeO2 nanozymes was collected by centrifugation, and added into 200 µL of acetate buffer (pH 4.0, 0.1 m) containing TMB (0.6 mm) and H2O2 (1.2 mm). Finally, the absorbance of the above reaction was measured after 30 min. Each experiment was repeated three times. The LOD was calculated by the equation LOD = (3σ/s), where σ is the standard deviation of blank signals and s is the slope of the calibration curve.
    5111 200 GeO2 Colorimetric Assay of OPs paraoxon Color 0.1-50 pM 14 fM
    5114 202 2.6Pt/EMT Detection of H2O2 and glucose H2O2 Color 2.9-29.4 μM 1.1 μM
    5113 202 2.6Pt/EMT Detection of H2O2 and glucose glucose Color 0.09-0.27 mM 13.2 μM
    5115 203 paper-based sensor MiRNA Detection. miRNA-141 E-chem 0.002-170 pM 0.6 fM 97.0–110.0%
    5116 203 paper-based sensor MiRNA Detection. miRNA-141 E-chem 0.002-170 pM 0.6 fM 97.0–110.0% the recoveries and RSD were in the range of 97.0–110.0 and 1.31–13.64%, suggesting a gratifying analysis capability of the proposed sensor for miRNA-141 in complex clinical samples.
    5122 209 BSA-RuO2NPs monitoring in situ H2O2 secretion from living MCF-7 cells. H2O2 Color 2-800 μM 1.8 μM
    5121 209 BSA-RuO2NPs monitoring in situ H2O2 secretion from living MCF-7 cells. H2O2 E-chem 0.4-3850 μM 0.18 μM
    5127 214 PTCA-ZnFe2O4 detection of ascorbic acid (AA) AA Color 1-10 μM 0.834 μM
    5128 215 hydrogel combating bacteria and accelerating wound healing
    5129 217 IrO2/GO detection of AA Ascorbic acid (AA) Color 5-70 Nm 324 nM The corresponding absorbance exhibited good linearity to the concentration of AA in the range of 5–70 μM with a coefficient of determination (R2) equal to 0.9931
    5130 217 IrO2/GO detection of AA Ascorbic acid (AA) Color 5-70 Nm 324 nM
    5131 220 MoS2@CGTC NCR MoS2@CGTC NCR achieves glucose-responsive TME self-modulation for enhanced cascaded chemo-catalytic therapy of tumors. MoS2@CGTC NCR achieves glucose-responsive TME self-modulation for enhanced cascaded chemo-catalytic therapy of tumors.
    5132 220 MoS2@CGTC NCR MoS2@CGTC NCR achieves glucose-responsive TME self-modulation for enhanced cascaded chemo-catalytic therapy of tumors.
    5133 221 VB2-IONzymes mouth ulcer healing
    5135 223 laccase@MMOFs industrial dye degradation
    5140 227 Fe SSN detection of glucose through a multienzyme biocatalytic cascade platform glucose Color 10-100 mM 8.2 μM
    5143 231 HKUST-1 Synergic Cancer Therapy
    5144 232 AuPtRu biothiol detection Biothiol
    5145 234 CdCo2O4 colorimetric detection of glucose glucose Color 0.5-100 μM 0.13 μM
    5146 235 GOx&PVI-Hemin@ZIF-8 enhanced cascade catalysis to detect glucose glucose Color 0-200 μM 0.4 μM
    5154 264 CeO2 microspheres colorimetric determination of phos-phoprotein concentration β-casein Color 0-600 μg/mL
    5156 266 FeBNC AChE activity and its inhibitor organophosphorus pesticides(OPs) detection paraoxon-ethyl Color 8-1000 ng/mL 2.19 ng/mL
    5155 266 FeBNC AChE activity and its inhibitor organophosphorus pesticides(OPs) detection acetylcholinesterase (AChE) Color 0.8-80 mU/mL 0.8 mU/mL
    5159 269 CMS NPs in vitro and in vivo treatment of MDR Bacterial Infections
    5160 270 CexZr1-xO2 photometric determination of phosphate ion phosphate ion Color 0.33-266.7 μM 0.09 μM
    5162 271 Co3O4 nanoflowers detection of acid phosphatase Acid phosphatase (ACP) Color 0.1-25 U/L 0.062 U/L
    5161 271 Co3O4 nanoflowers detection of acid phosphatase Acid phosphatase (ACP) Color 0.1-25 U/L 0.062 U/L it is capable of detecting ACP in serum samples
    5166 275 GO-CTAB-AuNP-hemin nanozymes Colorimetric apta-biosensing of amphetamin and methamphetamin methamphetamin 0.5–100 μM 154 nM
    5169 275 GO-CTAB-AuNP-hemin nanozymes Quantitative detection of amphetamin and methamphetamin amphetamin 0.5–100 μM 185 nM
    5168 275 GO-CTAB-AuNP-hemin nanozymes Quantitative detection of amphetamin and methamphetamin amphetamin 0.5–100 μM 185 nM detection and quantitation of AMP in a seized drug sample were performed
    5167 275 GO-CTAB-AuNP-hemin nanozymes Colorimetric apta-biosensing of amphetamin and methamphetamin methamphetamin 0.5–100 μM 154 nM MAMP detection in mixed drug samples was investigated
    5170 276 HRP@MOFs composite biomacromolecule embedding with excellent bioactivity
    5171 277 HIONCs-GOD synergistic chemodynamic−hyperthermia therapy H2O2
    5173 280 MoS2 NSs biosensing
    5174 281 MIL@GOx-MIL NRs anti-bacteria
    5175 282 Fe-SAs/NC biosensing acetylcholinesterase (AChE) fluorescence 2-70 U/L 0.56 U/L
    5176 284 LCDs biocatalysis
    5177 285 Fe3O4 anticancer
    5178 287 BM-20 nanosheets H2O2 detection H2O2 Color 1-1000 μM 0.4 μM
    5180 289 WS2 Pb detection Pb Color 5-80 μg/L 4 μg/L
    5182 292 RuTeNRs cancer treatment
    5186 296 GO-CeM (ex-situ) Sulfide (S2-) ion detection S2- Color 20-200 μM 11.70 μM
    5187 296 GO-CeM (ex-situ) Tin (Sn2+) ion detection Sn2+ Color 10-80 μM 5.58 μM
    5191 301 His-GQD/hemin detecting blood glucose glucose Color 2.5-200 μM
    5190 301 His-GQD/hemin detecting H2O2 H2O2 Color 5-240 μM
    5193 302 MoS2-MIL-101(Fe) detecting glucose glucose Color 0.01-15 μM 0.01 μM
    5192 302 MoS2-MIL-101(Fe) On the basis, a sensitive method for H2O2 detection was proposed with a linear range of 0.01−20 μmol/L and a detection limit of 10 nmol/L. Considering H2O2 as product in the reaction of glucose catalyzed by glucose oxidase, a sensitive and selective method for glucose detection was proposed. The method can be used in blood glucose detection with good accuracy. H2O2 Color 0.01−20 μM 10 nM
    5199 309 GDYO Detection of H2O2 and Glucose H2O2 Color
    5200 309 GDYO Detection of H2O2 and Glucose Glucose Color
    5205 313 Fe-Loaded MOF-545(Fe) Dye Degradation Dyes and the Removal of Dyes from Wastewater Color
    5207 316 Fe-MIL-88B we constructed an indirect competitive MOFLISA for high throughput determination of AFB1 in grain drinks AFB1 Color 0.01 to 20 ng·mL−1. 0.009 ng·mL−1 87–98% (Nestle peanut milk) 86–99%(Silk soy milk)
    5208 317 2D MnO2 nanoflakes detect microRNA Let-7a E-chem 0.4 to 100 nM 250 pM 105.4%, 96.3%, and 102.1%
    5210 320 Au-BNNs and Ag-BNNs nanohybrids Our results present new elements regarding BNNs-based nanohybrids which may help expand their applications in various fields such as catalyst, antimicrobial, biomedical, biosensor, and fillers in polymer matrix.
    5212 322 PDI-CeCoO3 Based on this, a colorimetric assay for GSH biosensing has been developed. GSH Color 1-10 M 0.658 μM
    5213 323 MnFe2O4/g-C3N4 H2O2 Color 50-100000 nM 20.5 nM
    5214 323 MnFe2O4/g-C3N4 An extremely sensitive colorimetric glucose sensor was fabricated using a novel hybrid nanostructure comprised of manganese ferrite oxide– graphitic carbon nitride (MnFe2O4/g-C3N4). Glucose Color 100nM-0.1mM/0.1mM-10mM 17.3nM/1.13μM 90.0-105.9%
    5216 324 Cu NCs detection of GSH GSH Color 1-150 μM 0.89 μM
    5215 324 Cu NCs detection of AA DFQ Fluor 0.5-30 μM 0.144 μM
    5217 324 Cu NCs detection of H2O2 H2O2 Color 0.01-1 mM 5.6 μM
    5219 326 SiO2@MPGs Imaging
    5220 327 Co4S3/Co3O4 nanotubes Antibacteria
    5221 328 Pc(OH)8/CoSn(OH)6 Detection of H2O2 and Cholesterol Cholesterol Color 0.1-1.0 mM 0.0109 mM
    5222 328 Pc(OH)8/CoSn(OH)6 Detection of H2O2 and Cholesterol H2O2 Color 0.4-0.8 mM 0.0914 mM
    5224 331 Fe-MOFs Detection of H2O2 and Glucose H2O2 Color 0-100 μM 1.2 μM
    5225 331 Fe-MOFs Detection of H2O2 and Glucose glucose Color 0-50 μM 0.6 μM
    5232 334 Au/MOFs(Fe, Mn)/CNTs Detection of H2O2, glucose and sulfadimethoxine glucose Color 0.005-0.3 μM 0.002 μM
    5229 334 Au/MOFs(Fe, Mn)/CNTs Detection of H2O2, glucose and sulfadimethoxine H2O2 Color 0.34-53.05 nM 0.18 nM
    5227 334 Au/MOFs(Fe, Mn)/CNTs Detection of H2O2, glucose and sulfadimethoxine glucose Color 0.005-0.3 μM 0.002 μM doutable
    5228 334 Au/MOFs(Fe, Mn)/CNTs Detection of H2O2, glucose and sulfadimethoxine H2O2 Color 0.34-53.05 nM 0.18 nM doutable
    5230 334 Au/MOFs(Fe, Mn)/CNTs Detection of H2O2, glucose and sulfadimethoxine sulfadimethoxine Color 0.54-41.58 μg/L 0.35 μg/L doutable
    5231 334 Au/MOFs(Fe, Mn)/CNTs Detection of H2O2, glucose and sulfadimethoxine sulfadimethoxine Color 0.54-41.58 μg/L 0.35 μg/L
    5234 336 OEG-AuNPs Detection of Hg2+ Hg2+ in saline solution 20-120 ppb 13 ppb
    5236 336 OEG-AuNPs Detection of Hg2+ Hg2+ in bottled water 10-40 ppb 2 ppb
    5237 336 OEG-AuNPs Detection of Hg2+ Hg2+ in Tap water 10-40 ppb 2 ppb
    5238 336 OEG-AuNPs Detection of Hg2+ Hg2+ in dH2O Color 10-60 ppb 0.9 ppb
    5235 336 OEG-AuNPs Detection of Hg2+ Hg2+ in seawater 20-100 ppb 10 ppb
    5240 337 N-QG Detection of H2O2 H2O2 Color 1-2000 μM 0.38 μM
    5239 337 N-QG Detection of H2O2 in milk H2O2 Color 2-1500 μM 0.75 μM
    5257 356 MoS2/rGO VHS excellent antibacterial effect in situ not only develops a new protocol to construct efficient nanozymes with capturing ability, as alternative antibiotics, but also provides new insight into the smart biomaterials design by defecting chemistry, integrating nanotopology, and catalytic performance
    5258 356 MoS2/rGO VHS excellent antibacterial effect in situ
    5260 357 PtNFs the quantitative detection of DHEA in human urine DHEA Color 2.1- 118.1 ng mL−1 1.3 ng mL−1
    5259 357 PtNFs the quantitative detection of DHEA in human urine DHEA Color 2.1- 118.1 ng mL−1 1.3 ng mL−1 The IC50 value is 15.7 ng mL−1, LOD is 1.3 ng mL−1, and the linear range is 2.1 ~ 118.1 ng mL−1,
    5262 358 50Co/CuS-MMT detection of H2O2 residue in contact lens solution H2O2 Color 10-100 μM 2.2 μM Fig. 6B displays that the absorbance at 652 nm was linearly correlated with H2O2 concentration from 10 to 100 μM and the limit of detection (LOD) was calculated to be 2.2 μM (LOD = 3 s/k, where s, k are the relative standard deviation of eight parallel controlled measurements and the slope of the linear calibration plots, respectively. In this formula, s = 0.000157, k = 2.14 × 10−4, and therefore, LOD =2.2 μM).
    5261 358 50Co/CuS-MMT detection of H2O2 residue in contact lens solution H2O2 Color 10-100 μM 2.2 μM
    5264 362 Aptamer-gold nanozyme to develop an Aptamer-nanozyme lateral flow assay (ALFA) CA125 in human serum CL 7.5-200 U/mL 5.21 U/mL
    5266 363 SNC TAC biosensor AA SERS 0.1-5 mM 0.08 mM the absorbance value.Under the optimal condition, the absorbance of ox-TMB decreases with the increase in AA concentration (Figure 4c).
    5265 363 SNC TAC biosensor AA SERS 0.1-5 mM 0.08 mM
    5270 364 Fe, N-CDs the H2O2 and xanthine determination in human serum and the urine H2O2 Color 0–100 μM 0.047 μM The detection limits of H2O2 and xanthine were 0.047 μM and 0.02 μM for ratiometric fluorometric and 0.05 μM and 0.023 μM for colorimetric, respectively.
    5267 364 Fe, N-CDs the H2O3 and xanthine determination in human serum and the urine xanthine Color 0-70 μM 0.02 μM The detection limits of H2O2 and xanthine were 0.047 μM and 0.02 μM for ratiometric fluorometric and 0.05 μM and 0.024 μM for colorimetric, respectively.
    5268 364 Fe, N-CDs the H2O3 and xanthine determination in human serum and the urine xanthine Color 0-70 μM 0.02 μM
    5269 364 Fe, N-CDs the H2O2 and xanthine determination in human serum and the urine H2O2 Color 0–100 μM 0.047 μM
    5271 366 Pd−Ir core-shell nanoparticles This work not only demonstrates the size effect, but also provides an effective strategy to enhance the performance of nanozymes in certain applications. 10- 2000 pg/mL 8.2, 4.6, and 3.7 pg/mL
    5272 366 Pd−Ir core-shell nanoparticles This work not only demonstrates the size effect, but also provides an effective strategy to enhance the performance of nanozymes in certain applications. 10- 2000 pg/mL 8.2, 4.6, and 3.7 pg/mL the limit of detection (LOD, which was defined by the 3SD method33) for the ELISAs were lowered from 9.3, to 8.2, 4.6, and 3.7 pg/mL when the size of Pd−Ir NPs was reduced from 13.0 to 9.8, 5.9, and 3.3 nm, respectively.
    5273 367 FeS2 NSs Simultaneously, the FeS2 NSs were applied to rapidly detect H2O2 concentrations in actual samples, such as lens solution, beer and disinfectant (all bought from supermarkets). H2O2 Color 0.02–4.00 μM 0.00760 μM
    5274 370 Cu3V2O7(OH)2·2H2O detection of glutathione glutathione Color 0.08 μM 93-109%
    5277 372 Cu2(OH)3NO3 detect biothiols in human blood serum On the basis of the oxidase-like catalytic of Cu2(OH)3NO3 nanosheets, a simple, quick, sensitive, and selective colorimetric assay was developed to determine biothiols. More interestingly, this technique was successfully applied to detect biothiols in human blood serum, suggesting it has a hopeful prospect for diagnostic in the relevant application.
    5276 372 Cu2(OH)3NO3 detect biothiols in human blood serum
    5281 376 ND nanozymes multifunctional antibacterial agents
    5285 378 rGO/CM (6 h) (2:1) glucose sensing activity glucose Color 1–50 μM 0.43 μM
    5286 378 rGO/CM (6 h) (2:1) glucose sensing activity Color 1–10 μM 0.15 μM Fig. 5d shows the HR-TEM images of rGO/CM (48 h) nanocomposites where large size (∼500 nm) polyhedrons are attached with rGO sheet.
    5284 378 rGO/CM (6 h) (2:1) glucose sensing activity Color 1–10 μM 0.15 μM
    5288 379 EPC-900 Colorimetric detection of ACP Acid phosphatase (ACP) Color 0.5-15 U/L 0.1 U/L
    5287 379 EPC-900 Colorimetric detection of ACP Acid phosphatase (ACP) Color 0.5-15 U/L 0.1 U/L The ΔA652nm value increased linearly with the increasing ACP activity from 0.5 to 15  U L−1.
    5289 379 EPC-900 luorometric sensing of glucose glucose Color 0.05–10 mM 30 μM
    5290 381 PdCu TPs/PG sensitive detection of HBe Ag HBe Ag Color from 60 fg·mL−1 to 100 ng·mL−1 20 fg·mL−1
    5292 383 AuNPs@Ag detect the viral HEV containing in fecal samples collected from HEV-infected monkey HEV-LPs Color 8.75 × 10−8– 10−11 g mL−1 4.3 × 10−12 g mL−1
    5293 385 Au@Pt nanoparticles a signal amplification strategy a widespread and dangerous phytopathogenic bacteria species (Clavibacter michiganensis)
    5297 387 Ag@Ag2WO4 NRs H2O2 and glucose sensing H2O2 Color 62.34~2400 μM 6.25 μM Since Glucose oxidase could be denatured at pH 3.0 acetate buffer solution, glucose detection was realized by the following procedure: 200 μL of glucose with different concentrations in 0.01 M acetate buffer solution (pH 5.0) was prepared with 50 μL of 10 mg mL-1 GOx and incubated at 37 °C for 30 min. This solution was then added to a mixture of 50 μL of 10 mM TMB, 100 μL of 0.5 mg mL-1 Ag2WO4 NRs and 200 μL of 0.1 M acetate buffer (pH 5.0). The mixed solution was incubated at room temperature for 30 min, and used for absorbance measurement at 652 nm.
    5295 387 Ag@Ag2WO4 NRs H2O2 and glucose sensing glucose Color 27.7~300 μM 2.6 μM
    5296 387 Ag@Ag2WO4 NRs H2O2 and glucose sensing H2O2 Color 62.34~2400 μM 6.25 μM
    5304 394 Fe3O4@CuO To evaluate the peroxidase catalytic performance of Fe3O4@Cu/C and Fe3O4@CuO composites, catalytic experiments were performed toward the oxidative degradation of model organic dyes (MB)
    5305 394 Fe3O4@Cu/C To evaluate the peroxidase catalytic performance of Fe3O4@Cu/C and Fe3O4@CuO composites, catalytic experiments were performed toward the oxidative degradation of model organic dyes (MB)
    5309 398 FePPOPBFPB By utilizing its superior peroxidase activity, rapid and visible detection ofS. aureus based on FePPOPBFPB was first established with acceptable specificity, sensitivity, and stability. S. aureus Color 100-107 CFU/ml 24 CFU/ml
    5317 417 Fe3O4@MoS2-Ag nanozyme antibacterial
    5319 419 core–shell Mn/Fe PBA@Mn/Fe PBA Colorimetric analysis Hg2+ Hg2+ Color 0.1-15 μM 0.02 μM
    5318 419 core–shell Mn/Fe PBA@Mn/Fe PBA Colorimetric analysis Cys Cys Color 1-25 μM 0.36 μM
    5320 419 core–shell Mn/Fe PBA@Mn/Fe PBA Colorimetric analysis of H2O2 H2O2 Color 1-300 μM 0.05 μM
    5321 420 ZnCo2O4 Colorimetric assay of pyrophosphatase (PPase) ppase Color 0.01-1 U/mL 0.004 U/mL
    5322 420 ZnCo2O4 Colorimetric assay of Pyrophosphate (PPi) ppi Color 0.05-1 mM 0.01 mM
    5324 421 Por-NiCo2S4 detect H2O2 and cholesterol with a very low detection limit H2O2 Color 0.02-1.0 mM 10.06 μM
    5323 421 Por-NiCo2S4 Determination of cholesterol in human serum cholesterol Color 0.1-9 mM 19.36 μM
    5326 422 BSA-PtNP@MnCo2O4 biosensing of glutathione GSH Color 1-10 μM 0.42 μM
    5325 422 BSA-PtNP@MnCo2O4 Determination of glucose glucose Color 10-120 μM 8.1 μM
    5365 450 RGD-BSA-CuCs catalytic cancer-specific DNA cleavage and operando imaging
    5366 451 PI/CdS detection of hypoxanthine hypoxanthine E-chem 0.010-10.0 mM 5.28 μM 95.5 %–105.9 % Human serum samples were diluted 20-fold with phosphate buffer solution (pH 7.4) in advance.
    5367 451 PI/CdS detection of hypoxanthine hypoxanthine E-chem 0.010-10.0 mM 5.28 μM 95.5 %–105.9 %
    5377 457 CuS-BSA-Cu3(PO4)2 detection of H2O2 H2O2 Color 0–8 μM 22 nM 98.12-101.9% Typically, using a standard addition method, H2O2 at 20, 50, and 100 nM is spiked into contact lens care solution obtained from a pharmacy. The H2O2 content present in lens care solution is determined from an already established calibration plot, generated at 654 nm using different H2O2 concentrations under the same assay mentioned above. Percentage recovery is assessed using Eq. (8), and the results are summarized in Table 3 (n = 3).
    5378 457 CuS-BSA-Cu3(PO4)2 detection of H2O2 H2O2 Color 0–8 μM 22 nM 98.12-101.9%
    5383 459 Ag-MA selective colorimetric and efficient removal strategy for mercury (II) Hg2+ ions Color 0.50-700 nM 0.18 nM 98.15–105.1 % Hg2+ ions in wastewater samples
    5381 459 Ag-MA selective colorimetric and efficient removal strategy for mercury (II) Hg2+ ions Color 1.0-600 nM 0.33 nM
    5382 459 Ag-MA selective colorimetric and efficient removal strategy for mercury (II) Hg2+ ions Color 0.10–700 nM 0.025 nM Fig. 6A illustrates the calibration detection curve for Hg2+ ions in buffer
    5384 459 Ag-MA selective colorimetric and efficient removal strategy for mercury (II) Hg2+ ions Color 1.0-600 nM 0.33 nM probe Hg2+ ions in blood
    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
    5389 463 ZV-Mn NPs Detection of hydrogen peroxide H2O2 Color 10–280 μM 0.20 μM
    5390 464 FePorMOF CL Imaging Assay of Glucose and AFP Glucose CL 50-1000 μM 39.2 μM
    5396 466 4-AHA@AuNPs nanoparticles selective determination of mercury and iron in ground water Fe3+ Color 5–50 ppb 4.0 ppb
    5395 466 4-AHA@AuNPs nanoparticles selective determination of mercury and iron in ground water Hg2+ Color 5-200 ppb 2.5 ppb
    5397 468 Ag2-xCuxS NPs Colorimetric urine glucose detection glucose Color 0-30 mM 0.37 mM The obtained glucose concentrations are mostly consistent with that tested by GOD-PAP biochemical analyzer in hospital (Table S2, SI).
    5398 468 Ag2-xCuxS NPs Colorimetric urine glucose detection glucose Color 0-30 mM 0.37 mM
    5400 469 V2O5 nanobelts glucose detection glucose Color 1-1000 μM 0.33 μM
    5399 469 V2O5 nanobelts glucose detection glucose Color 1-1000 μM 0.33 μM Online Monitoring of Glucose in Living Rat Brain
    5415 470 Tα-MOF The apparent Km of Tα-MOF is measured 3.180 mM and 0.0109 µM for TMB and H2O2, respectively. In this study, the LOD values for Ferulic acid, Tannic acid, and Chlorogenic acid were 0.19, 0.06, and 0.11, respectively. The RAC value obtained for tannic acid, orange juice, and lemon juice was 4.79, 3.37, and 3.53, respectively. Ascorbic acid (AA) Color 0-35 μM 0.39 μM Relatively, the extracts lead to a discoloring tendency in the order of Lemon Juice > Orange Juice > Eucalyptus > Cichorium intybus > Thymes > Morus
    5409 470 Tα-MOF The apparent Km of Tα-MOF is measured 3.180 mM and 0.0109 µM for TMB and H2O2, respectively. In this study, the LOD values for Ferulic acid, Tannic acid, and Chlorogenic acid were 0.19, 0.06, and 0.11, respectively. The RAC value obtained for tannic acid, orange juice, and lemon juice was 4.79, 3.37, and 3.53, respectively. Ascorbic acid (AA) Color 0-35 μM 0.39 μM
    5410 470 Tα-MOF The apparent Km of Tα-MOF is measured 3.180 mM and 0.0109 µM for TMB and H2O2, respectively. In this study, the LOD values for Ferulic acid, Tannic acid, and Chlorogenic acid were 0.19, 0.06, and 0.11, respectively. The RAC value obtained for tannic acid, orange juice, and lemon juice was 4.79, 3.37, and 3.53, respectively. Lemon juice Color 0-7 μM 0.08 μM
    5411 470 Tα-MOF The apparent Km of Tα-MOF is measured 3.180 mM and 0.0109 µM for TMB and H2O2, respectively. In this study, the LOD values for Ferulic acid, Tannic acid, and Chlorogenic acid were 0.19, 0.06, and 0.11, respectively. The RAC value obtained for tannic acid, orange juice, and lemon juice was 4.79, 3.37, and 3.53, respectively. Caffeic acid Color 0-20 μM 0.27 μM
    5412 470 Tα-MOF The apparent Km of Tα-MOF is measured 3.180 mM and 0.0109 µM for TMB and H2O2, respectively. In this study, the LOD values for Ferulic acid, Tannic acid, and Chlorogenic acid were 0.19, 0.06, and 0.11, respectively. The RAC value obtained for tannic acid, orange juice, and lemon juice was 4.79, 3.37, and 3.53, respectively. Quercetin Color 0-7.5 μM 0.11 μM
    5413 470 Tα-MOF The apparent Km of Tα-MOF is measured 3.180 mM and 0.0109 µM for TMB and H2O2, respectively. In this study, the LOD values for Ferulic acid, Tannic acid, and Chlorogenic acid were 0.19, 0.06, and 0.11, respectively. The RAC value obtained for tannic acid, orange juice, and lemon juice was 4.79, 3.37, and 3.53, respectively. Eucalyptus Color 0-15 μM 0.24 μM
    5414 470 Tα-MOF The apparent Km of Tα-MOF is measured 3.180 mM and 0.0109 µM for TMB and H2O2, respectively. In this study, the LOD values for Ferulic acid, Tannic acid, and Chlorogenic acid were 0.19, 0.06, and 0.11, respectively. The RAC value obtained for tannic acid, orange juice, and lemon juice was 4.79, 3.37, and 3.53, respectively. Thymes Color 0-35 μM 0.42 μM
    5401 470 Tα-MOF The apparent Km of Tα-MOF is measured 3.180 mM and 0.0109 µM for TMB and H2O2, respectively. In this study, the LOD values for Ferulic acid, Tannic acid, and Chlorogenic acid were 0.19, 0.06, and 0.11, respectively. The RAC value obtained for tannic acid, orange juice, and lemon juice was 4.79, 3.37, and 3.53, respectively. Morus Color 0-40 μM 0.47 μM
    5402 470 Tα-MOF The apparent Km of Tα-MOF is measured 3.180 mM and 0.0109 µM for TMB and H2O2, respectively. In this study, the LOD values for Ferulic acid, Tannic acid, and Chlorogenic acid were 0.19, 0.06, and 0.11, respectively. The RAC value obtained for tannic acid, orange juice, and lemon juice was 4.79, 3.37, and 3.53, respectively. Cichorium intybus Color 0-30 μM 0.37 μM
    5403 470 Tα-MOF The apparent Km of Tα-MOF is measured 3.180 mM and 0.0109 µM for TMB and H2O2, respectively. In this study, the LOD values for Ferulic acid, Tannic acid, and Chlorogenic acid were 0.19, 0.06, and 0.11, respectively. The RAC value obtained for tannic acid, orange juice, and lemon juice was 4.79, 3.37, and 3.53, respectively. Orange juice Color 0-8 μM 0.08 μM
    5404 470 Tα-MOF The apparent Km of Tα-MOF is measured 3.180 mM and 0.0109 µM for TMB and H2O2, respectively. In this study, the LOD values for Ferulic acid, Tannic acid, and Chlorogenic acid were 0.19, 0.06, and 0.11, respectively. The RAC value obtained for tannic acid, orange juice, and lemon juice was 4.79, 3.37, and 3.53, respectively. Trolox Color 0-35 μM 0.34 μM
    5405 470 Tα-MOF The apparent Km of Tα-MOF is measured 3.180 mM and 0.0109 µM for TMB and H2O2, respectively. In this study, the LOD values for Ferulic acid, Tannic acid, and Chlorogenic acid were 0.19, 0.06, and 0.11, respectively. The RAC value obtained for tannic acid, orange juice, and lemon juice was 4.79, 3.37, and 3.53, respectively. Chlorogenic acid Color 0-12 μM 0.11 μM
    5406 470 Tα-MOF The apparent Km of Tα-MOF is measured 3.180 mM and 0.0109 µM for TMB and H2O2, respectively. In this study, the LOD values for Ferulic acid, Tannic acid, and Chlorogenic acid were 0.19, 0.06, and 0.11, respectively. The RAC value obtained for tannic acid, orange juice, and lemon juice was 4.79, 3.37, and 3.53, respectively. Tannic acid Color 0-6 μM 0.06 μM
    5407 470 Tα-MOF The apparent Km of Tα-MOF is measured 3.180 mM and 0.0109 µM for TMB and H2O2, respectively. In this study, the LOD values for Ferulic acid, Tannic acid, and Chlorogenic acid were 0.19, 0.06, and 0.11, respectively. The RAC value obtained for tannic acid, orange juice, and lemon juice was 4.79, 3.37, and 3.53, respectively. Ferulic acid Color 0-12 μM 0.19 μM
    5408 470 Tα-MOF The apparent Km of Tα-MOF is measured 3.180 mM and 0.0109 µM for TMB and H2O2, respectively. In this study, the LOD values for Ferulic acid, Tannic acid, and Chlorogenic acid were 0.19, 0.06, and 0.11, respectively. The RAC value obtained for tannic acid, orange juice, and lemon juice was 4.79, 3.37, and 3.53, respectively. L-cysteine Color 0-30 μM 0.37 μM
    5418 471 Co2V2O7 particles GSH Detection GSH Color 2.5–20 μM 0.64 μM 97.4-98.7%
    5417 471 Co2V2O7 particles H2O2 and Glucose Detection H2O2 Fluor 0.008-3.2 μM 0.002 μM
    5416 471 Co2V2O7 particles H2O2 and Glucose Detection glucose Fluor 0.1–80 μM 0.03 μM 99.02-104.93%
    5419 471 Co2V2O7 particles H2O2 and Glucose Detection glucose Fluor 0.1–80 μM 0.03 μM 99.02-104.93% The glucose detection system also possessed good selectivity, and when the concentration of other sugars was 10 times higher than that of glucose (Figure 5f), no significant interference with the reaction system was observed.
    5423 478 DNA/MoS2 NSs Detection of carcinoembryonic antigen (CEA) in a sensitive manner carcinoembryonic antigen (CEA) Color 50-1000 ng/mL 50 ng/mL
    5425 483 DMSN@AuPtCo Decontaminate two kinds of wastewater and avoiding secondary pollution
    5427 484 Co3O4/MO3 Sense H2O2 and screen acetylcholinesterase activity and its inhibitor acetylcholinesterase (AChE) Color 0.005-1.0 U/L 0.1 mU/L
    5426 484 Co3O4/MO3 Sense H2O2 and screen acetylcholinesterase activity and its inhibitor H2O2 Color 0.1-200 μM 0.08 μM
    5428 485 CeO2 NCs Promise antibacterial performance
    5434 490 Zn-TCPP(Fe) Colorimetric detection of alkaline phosphatase Alkaline phosphatase (ALP) Color 50-200 U/L 50 U/L Three linear ranges of 2.5–20 U L−1, 5–60 U L−1, and 50–200 U L−1 could be obtained by using PPi, ATP, and ADP as inhibitors, respectively.
    5433 490 Zn-TCPP(Fe) Colorimetric detection of alkaline phosphatase Alkaline phosphatase (ALP) Color 50-200 U/L 50 U/L
    5441 497 CuS NPs Antibacterial treatment
    5444 500 CNF/FeCDs Smartphone-based colorimetric detection of hydrogen peroxide and glucose glucose Color 10-70 μM 1.73 μM
    5443 500 CNF/FeCDs Smartphone-based colorimetric detection of hydrogen peroxide and glucose H2O2 Color 6-42 μM 0.93 μM
    5446 502 M/CeO2 Detection of H2O2 and glucose H2O2 Color 10-100 μM 2 μM
    5447 502 M/CeO2 Detection of H2O2 and glucose glucose Color 0.01-1 mM 8.6 μM
    5450 506 Fe–N4 pero-nanozysome Hyperuricemia and Ischemic Stroke
    5453 509 AuNPs@C.CNF Detection of glucose glucose Color 1–60 μM 0.67 μM
    5452 509 AuNPs@C.CNF Detection of H2O2 H2O2 Color 0.5–30 μM 0.30 μM
    5456 512 NiCo2O4-Au composite for killing bacteria and disinfecting wound
    5458 515 aptamers@BSA-AuNCs for colorimetric detection of Salmonella typhimurium Salmonella typhimurium Color 101-106 cfu/mL 1 cfu/mL 92.4% - 110%
    5460 518 Hep-Pt NCs Colorimetric tests of H2O2 and glucose glucose Color 0.1 ∼ 2.0 mM 33 μM 98%-104.0%
    5468 525 Gold and magnetic particles (GoldMag) for determination of cholesterol cholesterol Color 0.018–1.4 mM 7.9 μM 98.57%-106.8%
    5473 529 man-PB for rapid detection of Escherichia coli O157:H7 (E. coli O157:H7) Escherichia coli O157:H7 (E. coli O157:H7) Color 0-108 cfu/mL 102 cfu/mL 90% - 110%
    5474 530 HCS@Pt NPs for photodynamic and catalytic synergistic tumor therapy
    5475 531 Zn-N-C-800 peroxidase-like activity
    5477 533 Ag-CoO NP for colorimetric sensing hydrogen peroxide and o-phenylenediamine o-phenylenediamine Color 1−20 μM 0.65 μM
    5476 533 Ag-CoO NP for colorimetric sensing hydrogen peroxide and o-phenylenediamine hydrogen peroxide Color 5-20 μM 3.47 μM
    5479 535 Fe-Nx SANs Detection of Aβ 1-40 Aβ 1-40 Color 1-2000 pg/mL 0.88 pg/mL
    5480 536 Cu/Au/Pt TNs Detection of microcystin-LR microcystin-LR Color 4.0-10000 ng/L 3.0 ng/L
    5482 537 MoS2/C-Au600 MoS2/C-Au600 with peroxidase-like activity can image cancer cells in the presence of TMB and H2O2
    5481 537 MoS2/C-Au600 Detection of H2O2 H2O2 Color 10-200 µmol/L 1.82 µmol/L
    5484 539 GA-NFs Detection of m‑cresol m‑cresol Color 0.05-0.5 mM
    5485 540 Fe3O4@CP Detection of GSH GSH Color 0.2-40 μM 0.05 μM
    5486 540 Fe3O4@CP Detection of H2O2 H2O2 Color 0.2-300 μM 0.11 μM
    5488 544 CuCo2S4 NPs For combating burn infections
    5489 545 NSP-CQDs NSP-CQDs was further utilized for antibacterial assays
    5490 546 Detection of acetylcholinesterase activity Detection of acetylcholinesterase activity acetylcholinesterase (AChE) Color 0.2-50 mU/mL 0.14 mU/mL
    5492 552 MnO2 nanoparticles Colorimetric detection of TATP TATP Color 1.57-10.50 mg/L 0.34 mg/L 105
    5493 553 CoMoO4 nanobelts Colorimetric detection of H2O2 H2O2 Color 0.5-25 μM 0.27 μM
    5494 554 Pd@Au nanostructures Detection of glucose glucose Color 0.02-2 mM 9.28 μM
    5497 557 Magnetic Nanoflowers this work documented MNPs PDA–Cu NFs as an efficient catalyst for catalytic reduction of organic dyes with the ability of facile recyclability. Additionally, MNPs PDA–Cu NFs were recognized as one of the nanozymes owing to peroxidase-like activity. Polydopamine and copper nanoparticles in MNPs PDA–Cu NFs have shown antimicrobial behavior toward Gram-negative bacteria (P. aeruginosa and E. coli) and Gram-positive bacteria (S. aureus).
    5498 558 Fe3O4@NH2-MIL-101(Fe) colorimetric detection of glucose glucose Color 1.7-750 μM 0.22 μM 100.5
    5499 559 Ni/Al–Fe(CN)6 LDH Determination of Cr (VI) Cr (VI) Fluor 0.067-10 μM 0.039 μM
    5500 560 Mesoporous Pd@Pt detection of atrazine atrazine Color 0.1-500 ng/mL 0.5 ng/mL 98.6-103.3
    5501 561 urchin-like Pt nanozymes monitoring of glycated albumin glycated albumin Color 10-5000 ug/mL 9.2 ug/mL 106-107
    5502 563 ficin@PCN-333(Fe) colorimetric detection of glucose glucose Color 0.5-180 μM 96 nM
    5503 565 Au–Ag@HA NPs Enhanced Cancer Therapy
    5504 566 Cerium Oxide NSs Detection of H2O2 H2O2 Electrode 20–100 mM 0.02 μM
    5505 567 Co3O4 NCs Detection of NO2 NO2 electrodes 0.3-1.5 ppm 0.3 ppm
    5506 568 Cu2O nanocubes Detection of S. aureus S. aureus Photoelectric 50-10e9 CFU mL−1 10 CFU mL−1
    5508 570 DNA-Cu/Ag NCs Detection of H2O2 H2O2 colorimetric 100-1000 μM 7.42 μM
    5509 571 N/Cl-CDs Detection of H2O2 H2O2 fluorescence 1-30 μM 0.27 μM
    5510 572 CFPN oxidation of natural organic matters
    5511 573 AgNPs@Fe3O4 Detection of cysteine cysteine colorimetric 0-20 μM 87 nM
    5512 574 Pt-HMCNs Detection of H2O2 H2O2 colorimetric 6.0-60 μM 2.81 μM
    5515 576 EMSN-PtNCs Detection of H2O2 H2O2 colorimetric 1-50 μM 0.87 μM
    5517 578 Co4S3 Antibacterial
    5519 580 WO3−x QDs detection of cholesterol cholesterol colorimetric 0.01-1.0 mM 3.0 μM
    5520 581 Fe–N–C detection of uracil DNA glycosylase uracil DNA glycosylase electrochemical 0.0005-1 U/mL 74 μU/mL
    5521 582 Ag5PMo12@PPy detection of uric acid uric acid colorimetric 1-50 μM 0.47 μM
    5522 583 FA-PMo4V8 detection of sarcosine sarcosine colorimetric 0.2-500 μM 0.311 μM
    5523 584 NMPs Antibacterial
    5526 588 PPy@MoS2@Au detection of tannic acid tannic acid colorimetric 1.0-100 μM 0.87 μM
    5527 590 GdW10O36 nanoclusters Antibacterial
    5529 592 Au−Cu2−xS photothermal therapy and chemical dynamic therapy
    5530 594 Pt/ZnCo2O4 Detection of ascorbic acid Ascorbic acid (AA) 1-15 μM 0.456 μM
    5535 599 Pd91-GBLP NPs the colorimetric detection of glucose glucose Color 2.5-700 μM 1 μM
    5536 600 PtNPs@PCs lead ion detection lead ion E-chem 0.05-1000 nM 0.018 nM
    5537 601 AuMS the selective colorimetric detection of dopamine Dopamine (DA) Color 10-80 μM 1.28 nM
    5538 602 Fe3O4 nanoparticles enhance the yield of DMBQ in the fermentation process
    5539 603 ACP/hemin@Zn-MOF ratiometric fluorescent arsenate sensing arsenate Fluor 3.33-300 μg/L 1.05 μg/L
    5540 604 GO/AuNPs detection of Hg2+ Hg2+ Color 5.2-120 nM 0.38 nM
    5543 606 Pt NPs-PVP theranostic application in acute kidney injury
    5544 607 Cu-rGO Colorimetric detection of H2O2 and glucose glucose Color 10-100 μM 10 μM
    5545 607 Cu-rGO Colorimetric detection of H2O2 and glucose H2O2 Color 10-100 μM 0.1 μM
    5547 610 FePc/HNCSs ynergistic Catalytic Therapy and Dual Phototherapy
    5549 613 NH2-MIL-53(Fe) dual-mode detection of prostate specific antigen PSA CL 1-30 ng/mL 0.3 ng/mL
    5550 613 NH2-MIL-53(Fe) dual-mode detection of prostate specific antigen PSA Fluor 0.5-30 ng/mL 0.2 ng/mL
    5555 618 MoO3−x NDs Near-Infrared Regulated Nanozymatic/Photothermal/Photodynamic Triple-Therapy for Combating Multidrug-Resistant Bacterial Infections
    5557 621 Au@Pt Ag+ detection by LSPR spectroscopy Ag+ Color 0.5-1000 μM 500 nM
    5558 622 TiO2/Bi2WO6/Ag heterojunction hydrogen sulfide detection H2S 0.5-100 μM 0.06 μM
    5559 622 TiO2/Bi2WO6/Ag heterojunction hydrogen sulfide detection H2S E-chem 0.5-300 μM 0.08 μM
    5562 625 Ceria NPs Acute Kidney Injury Alleviation
    5563 626 AuPd @MnO2 Detection of Tetrabromobisphenol A Tetrabromobisphenol A E-chem 0.44-46.49 ng/mL 0.10 ng/mL
    5566 629 DNA-Au/Pt NCs Detection of Staphylococcus aureus bacteria Color 102-108 CFU/mL 80 CFU/mL
    5567 630 POMOFs@PDDA-rGO Detection of H2O2 and Citric acid Citric acid 1–60 μM 2.07 μM
    5568 631 Fe-PorCOF Glucose sensing Glucose 0.01to 10.0 μmol·L-1 5.3 nmol·L-1
    5570 637 Magnetite@cellulose NCs Glucose monitoring Glucose 5 mM
    5572 639 WS2 QDs For Antibacterial and Anti-biofilm Therapie
    5576 647 MoSe2 Sening H2O2 Color 10-100 μM 4 μM
    5578 651 FeS2/SiO2 Detection H2O2 Color /L μM 0.00420 μM
    5579 651 FeS2/SiO2 Detection TMB Color 1-4- μM 0.16 μM
    5583 655 Cu-Carbon dots Detection Cr Fluor 0.2-100 μM 36 nM
    5585 657 iron oxides The activity curves and descriptors are expected to serve as a simple but robust theoretical tool for computer-aided screening and design of nanozymes, which could greatly facilitate the discovery of new nanozymes in the future.
    5586 658 AuNPs detection cysteine Color 0.5-20 μM 0.5 μM
    5587 658 AuNPs detection cysteine in biological fluids Color 0.5-50 μM 0.5 μM To this end, we tested human urine samples for different concentrations of cysteine using the system established in this paper.
    5589 660 Fe3O4/Au NPs detection of Staphylococcus aureus S. aureus Color 10 ~ 1000000 cfu/mL 10 cfu/mL
    5590 661 Fe-SAzyme detection of galactose TMB Color 50-500 μM 10 μM 104.83~105.33%
    5591 662 g-C3N4 detection of H2O2 H2O2 Fluor 90-2500 nM 73 nM
    5592 663 S-rGO detection of glucose TMB Color 1-100 μM 0.38 μM
    5594 664 NLISA-H detection of serum HAuCl4 Color 0.1-10 ng/mL 0.05
    5593 664 NLISA-T detection of serum TMB Color 0.1-10 ng/mL 0.08 ng/mL
    5595 665 GO-UO22+ NPs detection of uranyl ions TMB Color 5.9-943 μM 4.7 μM 96.82-98.31%
    5596 666 AuNCs-SF detection of H2O2 H2O2 Fluor 0.1-100 mM 0.072 mM 95.12-99.76%
    5598 668 D-Trp-OMe@AuNCs detection of trtracycline TMB Color 1.5-30.0 μM 0.20 μM 99.0-105.0%
    5599 669 GNR detection of dopamine DA Color 0.1–1, 2.5–50 μM 0.035 μM 90-110%
    5600 670 Fe3S4 detection of glucose glucose Color 0.5-150 μM 0.1 μM 93.7-101.4%
    5601 671 IrNPs antibacteria
    5602 672 MoS2-Lys NSs antibacteria
    5605 675 AIronNPs wound disinfection and healing
    5606 676 PBNPs-icELISA determination of free GCA GCA Color 0.03-1.20 μg/mL 2.5 × 10−3 μg/mL
    5612 683 BiVO4 detection of β-lactoglobulin β-lactoglobulin E-chem 0.01-1000 ng/mL 0.007 ng/mL
    5619 691 Fe-doped g-C3N4 nanoflake detection of sarcosine (SA) SA Color 10-500 μM 8.6 μM
    5618 691 Fe-doped g-C3N4 nanoflake detection of hydrogen peroxide (H2O2) H2O2 Color 2-100 μM 1.8 μM
    5627 701 Hep-Pd NPs determination of Pro protamine Color 0.02 ~ 0.8 μg mL−1 0.014 μg mL−1
    5631 705 ATF detection of cancer cells cancer cells 2000 cancer cells/mL
    5635 710 LaMNPs inhibition of the tumor growth
    5636 711 DhHP-6-c-ZrMOF promising catalyst for the high-efficiency degradation of phenol pollutants
    5641 717 Fe2O3/CNTs Highly Efficient Dopamine Sensing Dopamine (DA) Color 0-25 μM 0.11 μM
    5642 719 Fe-BTC H2O2 dection H2O2 Color 0.04-30 μM 36 nM
    5643 719 Fe-BTC glucose biosensing glucose Color 0.04-20 μM 39 nM
    5647 725 laccase/Fe-BTC-NiFe2O4 degrade pollutants in water
    5648 726 NH2-MIL-88B(Fe)-Ag wound-healing
    5649 727 Ir NPs detection of glutathione GSH Color 0.2-100 μM
    5650 727 Ir NPs detection of glucose glucose Color 0.01-2 mM 5.8 μM 93.3–104%
    5651 728 GOx@MOF One-step cascade detection of glucose at neutral pH glucose Color 8-140 μM 2.67 μM
    5656 733 Ti3C2 detect IR-b IR-b Color 0.5-8 ng/mL
    5655 733 paper-based sensors of His-Ti3C2 detection of glucose glucose Color 0.01-0.64 mM 0.01 mM
    5661 738 LIPIA as Chiral Scaffolds for Supramolecular Nanozymes
    5664 741 Fe-COFs detect H2O2 and degrade RhB H2O2 Color 10-2000 μM 5.6 μM 96.27-100.70%
    5667 744 Pt-GNRs cancer treatment
    5668 745 Pt/WO2.72 H2O2 detection H2O2 Color 0.005-12 mM 2.33 μM
    5669 745 Pt/WO2.72 glucose detection glucose Color 0.01-0.6 mM 5.9 μM
    5670 745 Pt/WO2.72 radical elimination
    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
    5679 753 Au/Cu2O In this work, we assessed the antioxidant behavior of three natural antioxidants (TA1, GA, TA2) on TMB oxidation catalyzed by Au/Cu2O heterostructures in the presence of H2O2 via colorimetric method tannic acid Color 0-16 μM 0.039 μM
    5680 753 Au/Cu2O In this work, we assessed the antioxidant behavior of three natural antioxidants (TA1, GA, TA2) on TMB oxidation catalyzed by Au/Cu2O heterostructures in the presence of H2O2 via colorimetric method gallic acid Color 0-75 μM 0.16 μM
    5681 753 Au/Cu2O In this work, we assessed the antioxidant behavior of three natural antioxidants (TA1, GA, TA2) on TMB oxidation catalyzed by Au/Cu2O heterostructures in the presence of H2O2 via colorimetric method tartaric acid Color 0-100 μM 1.55 μM
    5682 753 Au/Cu2O Therefore, it is vital important to explore a fast, sensitive method to accurate determination of H2O2 in the biological environment. On the basis of high peroxidase activity of Au/Cu2O nanocatalyst, a simple and flexible colorimetric sensor was constructed to detect H2O2 in this work. H2O2 Color 0.1-200 μM 0.054 μM
    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).
    5689 760 2Arg@FeOOH detect and remove inorganic arsenic from polluted water Arsenic Color 0.67-3333.33 μg/ml 0.42 μg/ml 95-105
    5693 766 nanoceria-PTA*-AuNPs conversion of 4-NP into 4-AP
    5694 768 Co3O4 HNCs colorimetric biosensing of dopamine DA Color 0.02-3.5 / 4.75–90 μM 0.015 μM 98.4%–101.6% As shown in Table S2, for the three groups of samples, the recovery rate is 96.0%–106.5% with low DA concentration, and 98.4%–101.6% with high DA concentration.
    5695 769 UiO-66-Fc detect H2O2 H2O2 Color 50 to 500 μM 0.23 μM
    5696 769 UiO-66-Fc detect glucose glucose Color 5-600 μM 2.32 μM
    5697 769 UiO-66-Fc detect Uric acid Uric acid Color 50-600 μM 1.18 μM
    5706 780 CuS-BSA-Cu3(PO4)2 Colorimetric sensing of dopamine in beef meat Dopamine (DA) Color 0.05–100 µM 0.13 µM
    5710 784 AuPt@SF (APS) Antitumor
    5711 785 GOD@ Cu-hemin MOFs colorimetric analysis of glucose glucose Color 0.01–1.0 mM 2.8 μM
    5712 787 ZnO-Co3O4 colorimetric detection of copper(ii) ions in serum copper(ii) Color 2-100 nM 1.08 nM As shown in Fig. S8,† the activity of our system kept over 90% after three recycles and only a minimal loss in the activity (<15%) was observed even after five recycles.
    5714 789 NiMn LDH used for the highly sensitive detection of H2O2 and ascorbic acid (AA). H2O2 Color 0.00125-0.03 mM 0.04 μM
    5715 789 NiMn LDH used for the highly sensitive detection of H2O2 and ascorbic acid (AA). Ascorbic acid (AA) Color 0-20 μM 0.014 μM
    5722 796 CuS-BSA-Cu3(PO4)2 Colorimetric assay for sensing dopamine (DA) Dopamine (DA) Color 0.05-100 μM 0.13 μM
    5724 798 PtPdCu TNAs Detection of Fe2+ and Evaluation of Antioxidant Capability Fe2+ Color 0.01-0.20 mM 0.005 mM
    5725 799 Ce/ZnCo2O4 Detection of H2O2 H2O2 Color 200-1000 μM 175 μM
    5726 799 Ce/ZnCo2O4 Detection of GSH GSH Color 2-15 μM 1.39 μM 101.0 − 103.5
    5731 806 CD44MMSN/AuNPs enhanced precise hepatocellular carcinoma therapy
    5736 812 Cu NCs a ratiometric H2O2 sensor H2O2 Fluor 0-1 mM 4.66 μM
    5737 812 Cu NCs The reactivity toward peroxide is utilized in specific and sensitive sensing of glucose glucose Fluor 0-1 mM 7.56 μM 99-99.6%
    5740 815 PANI@MoS2@Fe3O4/Pd Detection of hydrogen peroxide (H2O2) H2O2 Color 2.5-350 μM 1 μM
    5747 821 [Pyr]Ac- Ni0 detection of H2O2 H2O2 Color 400-4000 μM 120 μM
    5751 826 FeWOX NSs Sensing Cancer via Photoacoustic Imaging
    5754 828 Pt/CoFe2O4 Detection of H2O2 and DA Dopamine (DA) Color 20–80 μM 0.42 μM 95.5%-101.5%
    5753 828 Pt/CoFe2O4 Detection of H2O2 and DA H2O2 Color 0.1-0.9 mM 0.076 mM
    5756 830 CA@PtNi hNS Sensitive detection of HSA HAS Color 0–400 ng mL−1 0.19 ng mL−1 112-113%
    5757 831 PdFe/GDY Detection of GSH GSH Color 50-10000 nM 24.45 nM 86.0%-122.0% Based on the peroxidase-like activity of PdFe/GDY as well as the inspiration from the concept of enzymatic induced ROS mediating bacterial cell membrane destruction
    5759 833 Pt/CdS detect hydroquinone (HQ) HQ Color 1.0–10 μM 0.165 μM 83.56-91.76%
    5758 833 Pt/CdS detection of H2O2 H2O2 Color 0.10–1.00 mM 45.5 μM
    5760 834 CPP Nanoflare detection of H2O2 H2O2 Color 5 × 10−6 - 5000 × 10−6 M 1.2 × 10−6 M
    5761 834 CPP Nanoflare detection of H2O2 H2O2 Fluor 50 × 10−9 - 5 × 10−3 M CPP Nanozyme-Mediated Pathogens Elimination and Biofilm Eradication
    5762 835 AuVCs Detection of GSH GSH Color 25–500 μM 9.8 μM 99.64–104.71% The easy-to-use LFPB with smartphone could achieve a limit of detection of 9.8 μM and a wide range of 25–500 μM for GSH.
    5763 836 SVW11 glucose sensing glucose Color 1-1000 μM 1.14 μM
    5764 836 SV2W10 glucose sensing glucose Color 1-1000 μM 1.24 μM
    5770 843 GOx–Fe3O4@SHS It is therefore believed that by combining properties and functionalities of a wide range of available enzymes and nanozymes in the integrated system demonstrated herein would allow applications in biosensors, immunoassays, biofuel cells, and so forth.
    5775 848 sulfuration-engineered CoOx alkaline phosphatase activity sensing Alkaline phosphatase (ALP) Color 0.8-320 U/L 0.38 U/L
    5777 850 PCN-222(Mn) construct a novel sensitive nonenzymatic electrochemical hydrogen peroxide biosensor H2O2 E-chem 5 × 10^–7-1.01 × 10^–3 mol/L 3.1 × 10^–8 mol/L 99.4–105.6%
    5780 853 Fe-CDs ratiometric fluorescence assay for L-Cystein L-Cysteine Fluor 0.25-90 μM 0.047 μM
    5783 855 FeS2@C NSs glucose detection H2O2 Color 0.5-40 μM 0.17 μM
    5782 855 FeS2@C NSs glucose detection glucose Color 0.5-50 μM 0.19 μM
    5785 857 Fe3O4@Au@cDNA@H-GN colorimetric biosensing of nopaline synthase terminator nopaline synthase terminator Color 0.5-100 nM 0.19 nM
    5787 859 Co3O4-g-C3N4 degradation of environmental rhodamine B
    5788 860 Au–Ag–GOx HTNs NIR-II driven plasmon-enhanced cascade reaction for tumor microenvironment-regulated catalytic therapy.
    5789 861 g-CNOX trigger luminol-H2O2 to produce a long-lasting and intense chemiluminescence emission
    5790 862 MMoO4 Selective Detection of Aquatic Copper Ions Aquatic Copper Ions Color 0.1-24 μM 0.024 μM
    5792 864 2D Cu-TCPP nanofilm amplified electrochemical hydrogen peroxide sensing H2O2 E-chem 0.00008-8.1 mM 0.03 μM
    5796 869 Ag-Pt/rGO a convenient and sensitive method for the colorimetric determination of hydrogen peroxide was developed H2O2 10-100 μM 0.09 μM
    5797 870 Co-Al-Ce MMOs This novel Co-Al-Ce MMO also exhibits an antibacterial mode of action Gram-negative bacteria in near-neutral pH solution through generating ROS (mainly ·O ˉ 2) in the presence of H 2 O 2 . Ce containing MMO can be utilized as potential green marine antifouling material.
    5798 871 Cu-MOF This peroxidase-like mimics-based colorimetric aptasensor showed a rapid and sensitive quantification of E. coli E. coli 16~1.6 × 106 cfu/mL 2 cfu/mL
    5804 878 N/Cl-CDs a fluorescent platform is proposed for the determination of hydroquinone hydroquinone 1-75 μM 0.04 μM
    5806 880 Fe3O4@PAA/TMC/PEG sterilization E.coli and S.aureus bacteria.
    5807 881 FePOs anti-tumor protocol
    5808 882 Magnetite detect H2O2 H2O2 2.4 × 104 μAM−1 and 1.8 × 10−5 M
    5809 883 PVP-PtNC this “off-to-on” pathway makes the nanozyme-based colorimetric signal proportional to AMD concentrations, thereby circumventing the inherent drawbacks of limited signaling abilities and sensitivities with conventional signal-off immunoassay-based small molecule detection systems. AMD amantadine (AMD)
    5811 885 HGNs-Apt the current response of Ag had a good positive correlation with the GPC3 concentration Glypican-3 10.0–100.0 μg/mL 3.16 μg/mL
    5812 886 Co3Fe-MMOF detection of Aeromonas hydrophila Aeromonas hydrophila Color 62-6.2*108 CFU/mL 17 CFU/mL 60%-70%
    5813 887 PEI-600-Fe C-dots for Enhanced Synergistic Cancer Starving−Catalytic Therapy
    5814 888 GLAD Ni film Colorimetric Sensing of Uric Acid. Uric Acid Color 15−500 μM 3.3 μM
    5815 889 Ptn-JP NCs for glucose detection glucose Color 0.01 -1 mM 5.47 μM
    5817 896 Ptn-PEI NPs Glucose Detection glucose Color 0.01-5 mM 4.2 μM
    5820 902 VOxQDs Glucose Detection Glucose Detection Color 0.5-100 μM 1.7 μM
    5822 906 MNPs Detection E. coli membrane Color 104–108 CFU/mL 3.2 × 103 CFU/mL
    5825 909 Tungsten Disulfide Quantum Dots Detection of H2O2 H2O2 Color 0.1–60 μM
    5829 915 UiO-66(Fe/Zr)-NH2 sensing of Pi Fluor 0.2-266.7 μM 0.085 μM
    5831 921 g-C3N4/CeO2 analysis of Hg2+ ions Hg2 Color 0.2-1000 nM 0.085 nM
    5832 922 Ru/PC detection of H2O2 H2O2 Color 0.005-2.75 mM 3.8 μM
    5836 926 CuMnO2 NFs Antibacterial
    5837 926 CuMnO2 NFs wound healing H2O2
    5838 927 CHPB NPs Antibacterial We report for the first time the dual modality antibacterial application of CHPB NPs against both Gram-negative bacteria, Pseudomonas aeruginosa, and Gram-positive bacteria, Staphylococcus aureus.
    5839 928 BLGF-Au NCs quantitative detection of glucose glucose Colorimetric 5-100 μM 1.5 μM
    5840 929 PVP-AuNPs quantitative detection of mercury mercury Colorimetric 5-100 nM 1.9 nM
    5841 931 Cu-N-C SAzymes quantitative detection of glucose glucose Colorimetric 0.1-20 μM 0.05 μM
    5842 932 Fe-Ni-MOF quantitative detection of Sn2+ Sn2+ Colorimetric 1-4 μM 0.36 μM
    5843 933 Au-PDA-AAO quantitative detection of glucose glucose Colorimetric 0.5-50 μM 0.2 μM
    5847 937 Au-NPs-Cy-PVA quantitative detection of iodide ions iodide ions Colorimetric 0.12-5.42 μM 0.058 μM
    5848 938 PtPd NPs quantitative detection of lipocalin-2 lipocalin-2 conductometric 0.01-30 ng/mL 0.0059 ng/mL
    5850 941 D-His@AuNCs quantitative detection of doxycycline doxycycline Colorimetric 5.0-12.5 μM 1.0 μM
    5852 943 PTAC-MoS2 NS quantitative detection of glucose glucose Colorimetric 20-800 μM 18.34 μM
    5853 944 Au@PtRu nanorods quantitative detection of alcohol alcohol Colorimetric 0.25-4 mM 23.8 μM
    5854 945 Au-Hg/rGO quantitative detection of H2O2 H2O2 Colorimetric 5-100 μM 3.25 μM
    5855 946 ssCo3O4 quantitative detection of zearalenone zearalenone impedimetric 0.1-10000 fg/mL 33 ag/mL
    5860 956 Fe-N-C Alkaline phosphatase (ALP) Alkaline phosphatase (ALP) Color 0.05 – 20 U/L 0.03 U/L
    5863 959 Cu2O@Fe(OH)3 Immunosensor for the detection of ochratoxin A ochratoxin A Color 1-10000 ng/L 0.56 ng/L
    5865 962 Pt Immunochromatographic test strip for detecting aflatoxin B1 (AFB1) Color 0.05 – 10 ng /mL 0.03 ng /mL
    5866 963 N@GQDs Selective detection of dopamine Dopamine (DA) Color 0.12–7.5 mM 0.04 μ M
    5867 964 CeO2-CDs Ratiometric fluor escence detection of H 2 O 2 and cholesterol cholesterol Fluor 1.66 -1.65 μ M-mM 0.49 µM
    5868 965 Fe3O4@Au Detection of dopamine Dopamine (DA) E-chem 0.01 – 1 mmol/L 0.0109 mg/L
    5869 966 Au Detection of uric acid in human serum and urine Uric acid Color 0.1 to 30 μ M 0.04 μ M
    5870 967 Au Detection of arsenite Arsinite Color 0.01 – 11.67 mg/L 0.008 mg/L
    5871 968 P2W18Fe4/PDA For glutathione and Escherichia coli O157: H7 detection GSH Color 2- 8 mM 0.18 mM
    5872 969 PNPG-PEG Colorimetric detection of chromium (VI) ion Hexavalent chromium [Cr(VI)] Color 0.01 – 0.1 μ M 0.012 μ M
    5874 971 PdPtBP MNPs/MXene KIM-1 H2O2 0.5-100 ng/mL 86 pg/mL
    5876 973 Fe3O4@SiO2-NH2-Au@Pd0.30NPs-protG antip53aAbs detetion anti-p53aAbs Color 1-500 ng/mL 15 pg/mL
    5877 974 GQD Cancer treatment TMB Color
    5878 975 RuO2 Oxidative stress related disease treatment
    5880 977 RuO2 Oxidative stress related disease treatment
    5882 979 Co3O4/BiPc(OC8H9)12 Glutathione detection TMB Color 10–200 μM 0.35 mM
    5883 980 CNQDs@MA-Ag Hg2+ sensing TMB Color 0.010-25 μM 0.050 nM
    5884 981 FePd RhB degradation TMB Color
    5885 982 PDA/Hemin-CD cholesterol Sensing TMB Color 0.5–10 μM 0.38 μM
    5886 983 FeP-pSC4-AuNPs H2O2 detection ABTS Color
    5888 984 Cu-NC Glucose detction glucose oxidase Color 0.1-400 100 nM
    5887 984 Cu-NC H2O2 detection TMB Color 0.01-100 10 nM
    5889 984 Cu-NC Ascorbic acid detction Ascorbic acid (AA) Color 0.1-500 90 nM
    5890 986 SA-Fe/NG detection of Cr5+ Cr4+ Color 30-3000 nM 3 nM 101.52%-113.67%
    5891 987 NMAs detection and elimination of cationic dyes
    5894 988 Cy-AuNCs detection of glutathione reductase (GR) GR Color 0-0.2 U/mL 0.003 U/mL
    5892 988 Cy-AuNCs detection of glutathione (GSH) GSH Color 0-0.4 mM 0.01 mM
    5893 988 Cy-AuNCs detection of glutathione disulfide glutathione disulfide Color 0-2.5 mM 0.03 mM
    5896 989 2D Co-MOF detection of ALP Alkaline phosphatase (ALP) Color 0.33 U/mL
    5895 989 2D Co-MOF detection of AA AA Color 0.47 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%
    5899 992 Fe3O4@Pt@E5 AML treatment
    5900 993 CeO2 Measurement of HX HX Color 50-800 μM 15 μM
    5903 996 Fe-HCl-NH2-UiO-66 NPs Detection of H2O2 H2O2 Color 3.125-100 μM 1.0 μM
    5904 997 MoS2 determination of D-penicillamine D-penicillamine Color 7.0-60 μg/mL 0.63 μg/mL
    5905 998 CoSe2 determination of D-penicillamine No Significant loss in peroxidase like activity even after 365 days.
    5908 999 CS@GSH-CuNCs detection of AChE activity. Color 10-120 mU/mL 3.3 mU/mL
    5906 999 CS@GSH-CuNCs detection of choline Color 20-150 μM 6.5 μM
    5907 999 CS@GSH-CuNCs detection of choline Fluor 5-100 μM 1.2 μM
    5909 999 CS@GSH-CuNCs Fluor 5-100 mU/mL 1.4 mU/mL
    5910 1000 Fe-MOFs detection of F- F- Color 10.0-200.0 μM 4.2 μM
    5913 1005 Pt-PIL-MWCNTs Detection of Glucose Glucose Color 160-900 μM 50 μM
    5914 1005 Pt-PIL-MWCNTs Detection of H2H2 H2O2 Color 10-1000 μM 5.5 μM
    5915 1006 Fe3O4/DG detection and degradation of harmful triazine pesticides 2.24 μM
    5917 1008 NiCo2S4 Detection of Glucose Glucose Color 20-200 μM 5.19 μM
    5918 1009 Hemin⊂MIL-88-NH2 Detection of H2H2 H2O2 E-chem 0.5-203 μM 0.06 μM
    5919 1010 αFe2O3NPs β-glucan sensing β-glucan Color 1.0-15 ng/mL 0.5 ng/mL
    5926 1017 Pd-Ir nanocubes immunoassay of nucleocapsid protein from SARS-CoV-2 NP Color 0.023 ng/mL
    5927 1017 Pd-Ir nanocubes immunoassay of nucleocapsid protein from SARS-CoV-2 PSA Color 0.348 pg/mL
    5933 1025 Co1.5Mn1.5O4 report an eco-friendly sol-gel approach for synthesizing bimetallic oxide-Co1.5Mn1.5O4
    5934 1026 dsDNA-AuNP@MABs determination of acetamiprid. acetamiprid Color 0.4-4.5 ppb 0.24 ppb
    5935 1027 Cr@Ag NP Determination of Hg2+ Hg2+ Color 5 nM
    5937 1029 CNCs@AuNPs catalyzing the reduction of hydrogen peroxide (H2O2) to initiate a characteristic color reaction at acidic pH and the disproportionation of O2•− producing O2 and H2O2 at alkaline pH, respectively
    5939 1031 bioconjugated nanoflowers Detection of Glucose Glucose Fluor 0.2-300 mg/dl
    5941 1034 pyrite nanozyme apoptosis−ferroptosis synergistic tumor therapy
    5942 1035 MnFe2O4/C@Ce6 a promising innovation in tumor treatment using PDT
    5943 1036 Modified Co3O4 Nanozymes H2O2 detection H2O2 Color 0.01 to 40 mmol L−1 1.5 μmol L−1
    5944 1038 Fe3O4@MIL-100(Fe)-Au detection of H2O2 H2O2 Color
    5945 1039 Cu-PBG kill Gram-positive and Gram-negative bacteria with the assistance of H2O2 both in vitro and in vivo
    5946 1041 Mn3O4 NPs and NC Mn3O4 NPs and NC can be used as PPO mimics in the potential fields such as biosensing and removal of phenolic compounds in industrial waste waters.
    5947 1042 YVO4 detection of H2O2 H2O2 Color 0.5-50 μM 0.126 μM
    5948 1043 Ch-MoS2-Au@Pt specific biorecognition and catalyzed reduction of H2O2 H2O2 E-chem 1 × 10− 4 -200 ng mL− 1
    5949 1044 GSH-Au/Pt NCs Colorimetric detection of Cys cysteine Color 0.5 to 30 μM 0.154 μM
    5950 1045 PtO2 Colorimetric detection of H2O2 and glucose Glucose Color 0.05 ~ 1.5 mM 10.8 μM
    5951 1045 PtO2 H2O2 Color 0.05 to 2 mM 6.3 μM
    5952 1046 Au/Ni-Fe LDH/rGO SERS sensing of Hg2+ Hg2+ Color 0.01-0.20 μM 0.01 μM
    5953 1046 Au/Ni-Fe LDH/rGO SERS sensing of MeHg MeHg Color 0.01-0.10 μM 0.01 μM
    5954 1046 Au/Ni-Fe LDH/rGO total removal of organic mercury
    5957 1049 Ag4[Fe(CN)6] detection of glucose glucose Color 1.0-500 μM 0.32 μM
    5958 1049 Ag4[Fe(CN)6] detection of ALP Alkaline phosphatase (ALP) Color 10-100 U/L 3.3 U/L
    5959 1049 Ag4[Fe(CN)6] detection of AChE acetylcholinesterase (AChE) Color 0.25-50 U/L 0.083 U/L
    5964 1056 WS2 nanosheets Detection of Kanamycin Kanamycin Color 0.1-0.5 μM 0.06 μM
    5966 1058 MoS2@CoFe2O4 determination of cysteine (Cys) Cys Color 0.5-15 μM 0.10 μM 95.3% and 96.0% with the RSD of 2.1% and 4.2%
    5967 1058 MoS2@CoFe2O4 determination of glutathione (GSH) GSH Color 0.5-35 μM 0.21 μM
    5975 1062 Fenozymes Superoxide Scavengers
    5977 1064 Pt-LNT NCs detection of glucose glucose Color 5-1000 μM 1.79 μM
    5978 1065 GCDs glucose detection glucose Color 0-40 μM 0.5 μM
    5980 1067 BNQDs/CeO2 detection of kanamycin kanamycin Color 0.01-100 nM 4.6 pM
    5981 1068 SiO2@Pt NPs detection of mercury ions Hg2+ Color 0.005-5000 nM 60 fM
    5983 1070 1-M a versatile redox-catalysis platform
    5984 1072 Co(OH)2/FeOOH/WO3 detection of human cervical cancer cells HeLa cancer cells Color 50-50000 cells/mL 12 cells/mL
    5987 1076 MnO2-Dox@HFn overcome tumor hypoxia
    5988 1077 WS2 nanosheets detect acetone acetone Color 10-125 mg/L 3.08 mg/L 85.8-107.5%
    5990 1079 Copper Nanozyme degradation of methyl orange pollutants methyl orange
    5991 1082 G3.0-he in-situ forming hydrogel
    5992 1083 MFNCDs detect Glucose H2O2 Color 100 nM – 2 mM 84 nM
    5993 1083 MFNCDs detect Glucose glucose Color 500 nM – 1 mM 0.41 μM
    5994 1083 MFNCDs detect Glucose H2O2 Fluor 100 nM – 2 mM 97 nM
    5995 1083 MFNCDs detect Glucose glucose Fluor 500 nM – 1 mM 0.85 μM
    5996 1084 CuMnFe-ATP detecct H2O2 H2O2 Color 0.5− 100.0 μM/L 0.047 μM/L 99.7-103.0%
    5998 1086 FeVO4 not only provides new and sensitive technique for 5fC detection, but also offers new biomarker and new evaluation method for eco-toxicological effects of heavy metals 5-formylcytosine (5fC) nucleotide PEC signal 0.1-400 nM 0.062 nM
    6000 1092 SnO2/GCN detect H2O2 H2O2 Color 10-655 μM 0.3 μM
    6003 1095 GOQD-q-CuO detect glucose H2O2 Color 2.5–200 μM 0.5 μM
    6004 1095 GOQD-q-CuO detect glucose glucose Color 5–400 μM 2.5 μM
    6005 1096 CDs@ZIF-8 detect GSH GSH Color 0-100 μM 1.04 μM
    6006 1096 CDs@ZIF-8 detect GSH H2O2 Color 0.1-1.0 mM 3.6 μM
    6009 1102 Pt/UiO-66 detect glucose glucose Color 0.1−1.33 mM 0.033 mM
    6010 1104 CuMn2O4 detect L-cysteine L-cysteine. Color 50-200 μM 54.15 μM
    6011 1104 CuMn2O4 detect H2O2 H2O2 Color 0.5-22 mM 0.11 mM
    6014 1107 Mn/PSAE Tumor Therapy via Integrated Cascade Reactions
    6019 1111 MoSe2/CoSe2@PEG for NIR-Enhanced Chemodynamic Therapy
    6022 1115 CeO2 Melamine Detection Melamine Color 0.004-1.56 nM 4 pM
    6023 1115 ATP‐CeO2NRs Melamine Detection Melamine Color 0.2–3.12 nM 17 pM
    6025 1118 Cu NanoZyme detection of glucose in human urine glucose Color 0.5-15 mM 0.45 mM
    6026 1119 N/I-CDs photocatalytic antibacterial and wound disinfection
    6027 1120 ZnO-Co3O4 NCs Colorimetric determination of amyloid-β peptide Aβ monomer Color 5-150 nM 3.5 nM
    6028 1121 CPMP tumor chemodynamic therapy
    6030 1126 g-CNQDs fluoride ions detection fluoride ions detection Color 10-120 μM 4.06 μM
    6031 1127 1-Me-D-Trp@AuNCs Norfloxacin detection Norfloxacin detection Color 1.25~8.0 μM 0.2 μM
    6032 1128 ZnSA-AuAMP hydrogel detection of ALP Alkaline phosphatase (ALP) Color 0.47-10.03 U/L 0.09 U/L
    6034 1130 CuS/g-C3N4 Ibuprofen can be detected Ibuprofen Color 0-100 mg/L 21.20 mg/L
    6035 1130 CuS/h-BN Ibuprofen can be detected Ibuprofen Color 0-100 mg/L 16.01 mg/L
    6038 1135 Ni–Pt NPs colorimetric immunoassay of carcinoembryonic antigen carcinoembryonic antigen (CEA) Color 5-500 pg/mL 1.1 pg/mL
    6041 1138 AOX–CF–H-Au detection to ethanol ethanol E-chem 0.01–0.15 mM 0.005 mM
    6042 1138 GOX–CF–H-Au detection to glucose glucose E-chem 0.1–0.9 mM 0.05 mM
    6044 1145 C-IONPs exhibits an excellent specificity for OVCAR3 cell-derived exosomes exosome E-chem 6.25 × 10^5-1.0 × 10^7 exosomes/mL 1.25 × 10^6 exosomes/mL
    6045 1148 Pd NCs quantitatively monitoring heparin in aqueous solution and biological fluid heparin Color 0.5–25 µg mL−1 1.1 ng mL−1
    6046 1149 SrTiO3/DHB Amplified detection of G-6-P and G6PD G6PD Color 1.4 × 10–5–14 U/mL 5.7 × 10–6 U/mL
    6047 1149 SrTiO3/DHB Amplified detection of G-6-P and G6PD G-6-P Color 0.05–100 μM 0.016 μM 99.3%-103.0% G-6-P in spiked serum sample
    6048 1151 Fe-CoO NCs a facile and sensitive colorimetric sensor to detect H2O2 and dopamine (DA) H2O2 Color 6–20 μM 4.40 μM 97.6-106.4%
    6049 1151 Fe-CoO NCs a facile and sensitive colorimetric sensor to detect H2O2 and dopamine (DA) Dopamine (DA) Color 2–10 μM 1.99 μM 94.6–107.2%
    6051 1156 Fe3O4/CeO2/C-dot nanocomposite H2O2 detection H2O2 Color 5.0 × 10^–13–1.0 × 10^–6 M 5.0 × 10^–13 M
    6052 1157 MOF-199 detection of Cr(VI) Cr(VI) Color 0.1–30 μM 0.02 Μm 93.1-103%
    6054 1159 CeO2@C antifouling
    6059 1165 CuNFs immunoassay demonstrates high sensitivity for IV/A influenza virus (IV)/A 10–10*6 fg mL−1 32.37 fg mL−1 a limit of detection (LOD) as low as 32.37 fg mL−1 and 54.97 fg mL−1 in buffer and serum, respectively. For practical needs, a clinically isolated IV/A/H3N2 and spike protein of SARS-CoV-2 were detected with the LODs of 17 pfu mL−1 and 143 fg mL−1, respectively.
    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
    6061 1167 Cu2O NPs colorimetric biosensing for glucose and l-cysteine glucose Color 1-1000 μM 2.19 μM
    6062 1167 Cu2O NPs colorimetric biosensing for glucose and l-cysteine l-cysteine Color 0-10 μM 0.81 μM
    6063 1169 GK-Pd NPs selective and sensitive detection of cholesterol cholesterol Color 5-100 μM 3.7 μM
    6080 1191 PdCo@MSNs Colorimetric detection of GSH glutathione Color 2-20 μM 0.33 μM
    6082 1193 rGO/CMCNs colorimetric detection of neurotransmitter dopamine in blood serum and urine samples Dopamine (DA) Color 1-10 μM 0.17 μM
    6083 1194 Pt/NiCo-LDH NCs Fast colorimetric sensing of H2O2 and glutathione H2O2 Color 10-90 mM 0.76 mM
    6084 1194 Pt/NiCo-LDH NCs Fast colorimetric sensing of H2O2 and glutathione glutathione Color 50-500 mM 3.77 mM
    6093 1209 Cu/CeS Cu/CeS-based sensor for H2O2 determination showed high sensitivity H2O2 1.5–20,000 μM 0.42+0.006
    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.
    6095 1214 Cu2+-HCNSs-COOH a colorimetric sensing platform by detecting the absorbance of the 3,3′,5,5′-tetramethylbenzidine-H2O2 system at 652 nm for quantifying H2O2, which holds good linear relationship between 1 and 150 μM and has a detection limit of 0.61 μM. H2O2 1-150 μM 0.61 μM
    6097 1217 B-Doped core–shell Fe@BC nanozymes combat bacteria
    6101 1223 CoFe2O4 an antioxidant cobalt ferrite (CoFe2O4) nanozyme as a bridge between nanotechnology and biological nitrogen fixation, which was shown to efficiently regulate the reactive oxygen metabolism and protect nitrogenase, thereby significantly enhancing the symbiotic nitrogen fixation efficiency by 260% in Glycine max (L.) Merr. (soybean). The CoFe2O4 nanozyme was also revealed to effectively reduce the concentration of ROS in the nodule by 56.6%, creating a superior environment for the proliferation of rhizobia and forming more effective nodules (larger nodules for an increase of 45.6% in the number of parasitic rhizobia). Furthermore, the CoFe2O4 nanozyme was shown to act as a synergist of leghemoglobin and increase its accumulation by 45.9%, where the high concentration of leghemoglobin in nodular cells can create a relatively hypoxic environment and protect nitrogenase, thus achieving a quantitative leap in nitrogen fixation capacity and simultaneously increasing the soybean photosynthesis by 67.2%. Our study has demonstrated that the CoFe2O4 nanozyme can efficiently regulate the intracellular ROS metabolism and serve as a promising strategy for enhancing symbiotic nitrogen fixation. ROS
    6102 1224 CuCo2O4 microspheres detection of H2O2 H2O2 Color 1.00-10.00 mM 132.70 μM
    6103 1224 CuCo2O4 microspheres detection of AA AA Color 1.00-10.00 μM 0.57 μM
    6109 1235 Fe-N-C single atom Alkaline phosphatase activity detection Alkaline phosphatase (ALP) Color 0.1-1.5 U/L 0.05 U/L
    6112 1240 Cu-CDs Cr(III) detection Cr(III) Fluor 5×10^-6-1.5×10^-4 mol/L 1.2×10^-7 mol/L
    6114 1242 MoS2@Au Salmonella typhimurium detection Salmonella typhimurium Color 10^2-10^7 lg (CFU/mL) 100 lg (CFU/mL) 84.34 ± 5.90 % (n = 3) to 118.92 ± 3.61 % (n = 3)
    6115 1243 carbon polymer hollow spheres (CPHSs) Detection of H2O2 H2O2 Color 50-500 μM 10 μM
    6118 1248 Fe3O4@PDA@Pd/Pt HCG, a clinic marker of pregnancy HCG Color 0.01-4 mIU/mL 0.0094 mIU/mL
    6119 1248 Fe3O4@PDA@Pd/Pt E. coli O157:H7 E. coli O157:H7, one of the important foodborne pathogens Color 100-100000 (CFU/mL 90 (CFU/mL
    6120 1249 Fe3O4 Neuroprotective
    6126 1260 MTex Biofilm Eradication
    6127 1261 GOx@Fe-ZIF-8 glucose sensing glucose Colorimetric
    6129 1263 USPBNPs treatment of ROS-related diseases and MRI-guided diagnosis and treatment
    6130 1264 Mn3O4 quantitative detection of GSH GSH colorimetric 0.1-30 μM 20.0 nM
    6133 1268 H2TCPP/ZnS/CoS quantitative detection of Hg2+ Hg2+ colorimetric 40−1000 nM 17.74 nM
    6138 1277 Cu2+/PPy NTs quantitative detection of H2O2 H2O2 Colorimetric 4-100 μM 1.62 μM 98.5%–104.4%
    6142 1281 CD N/Au selective detection of ultratrace K+ K+ Fluor 0.06–1.3 nM 0.024 nM
    6143 1282 Pd NSs detection of H2O2 H2O2 Color 10-100 μM 13.4 μM
    6144 1283 Ag NFs quantitative detection of ascorbic acid Ascorbic acid (AA) 2.0-70.0 μM 0.1 μM
    6145 1284 CQDs quantitative detection of H2O2 H2O2 Colorimetric 5.00–60.0 μM 0.86 μM
    6147 1287 GNE-based Au NPs Glucose Biosensor glucose Color 0.05-10 mM
    6148 1287 GNE-based Au NPs H2O2 detection H2O2 CL
    6149 1289 GOx@CuBDC Gluose detection TMB Color 10-500 μM 4.1 μM
    6150 1292 0.10CeO2/CoO NCs human Urine L-cystein sensing Color 5-10 μM 3.71 μM
    6151 1295 RSPCO pyrogallol Sensing TMB Color 0.5-30 μM 15 nM
    6152 1297 Rh NPs Immunosensor for Ferritin (RhNPs-lateral flow immunoassay with enhancement ) Ferritin Color 0.01-5 ng/mL 0.3 ng/mL
    6153 1297 Rh NPs Immunosensor for Ferritin (RhNPs-lateral flow immunoassay without enhancement ) Ferritin Color 0.1-10 ng/mL 0.4 ng/mL
    6156 1303 Au@Pt NRs Detection of Ascorbic Acid Color
    6157 1304 Ag2S@Fe2C-DSPE-PEG-iRGD Therapy for breast cancer TMB Color
    6158 1305 MoS2 Salmonella typhimurium Salmonella typhimurium Color 10*3 CFU/mL
    6159 1306 CeO2 NRs@polymer Catalytically Generate Oxidative Stress for Tumor Therapy Tumor Resonance Raman
    6163 1310 MnO2@polymer On-site monitoring of oxalate Oxalate Color 0.8 μ M
    6167 1314 Pt NPs Detection of mercury in environmental water samples Mercury E-chem
    6169 1316 Fe3O4 NPs detection of hydroxyl radical scavenging activity ·OH Color
    6172 1324 PBBA detection of glycated albumin glycated albumin Color 10-20000 μg/mL 7.32 μg/mL
    6173 1324 PBBA detection of glycated albumin glycated albumin E-chem 5-1000 μg/mL 3.47 μg/mL
    6174 1325 GOQD-MPS degradation of organic dyes
    6175 1326 SBA-AmPA/Au reduction of 4-nitrophenol
    6176 1327 LaFeO3 Detection of gallic acid gallic acid Color 0.6-36 μM 0.4 μM
    6177 1328 Fe-MIL-88NH2 detection of catechol catechol Fluor 0.125-5 μM 0.0913 μM
    6179 1330 CWNSs detection of H2O2 H2O2 Color 0.5-100 μM 0.15 μM
    6180 1332 CSFs detection of H2O2 H2O2 Color 10-100 μM 3.33 μM
    6182 1336 MOF Eu-pydc detection of H2O2 H2O2 Color 10-300 μM 1.67 μM
    6183 1336 MOF Eu-pydc detection of glucose glucose Color 10-1000 μM 6.9 μM
    6184 1336 MOF Eu-pydc detection of cysteine cysteine Color 0-4 μM 0.28 μM
    6186 1340 V2O5-Mt detection of H2O2 H2O2 Color 30-400 μM 4.0 μM
    6187 1340 V2O5-Mt detection of GSH GSH Color 0.1-30 μM 0.069 μM
    6188 1341 PMA-MOF detection of H2O2 H2O2 Color 1-100 μM 0.222 μM
    6189 1341 PMA-MOF detection of AA AA Color 3-100 μM 0.0046 μM
    6190 1342 AgNPs@GQDs detection of H2O2 H2O2 Color 0.08-40 μM 0.025 μM
    6191 1342 AgNPs@GQDs detection of H2O2 H2O2 Fluor 2-60 μM 0.83 μM
    6192 1342 AgNPs@GQDs detection of glucose glucose Color 0.5-50 μM 0.17 μM 92.89%–104.44%
    6193 1342 AgNPs@GQDs detection of glucose glucose Fluor 5-100 μM 1.31 μM
    6196 1346 Cu-MOF colorimetric aptasensor for chlorpyrifos chlorpyrifos Color 0-1250 ng/mL 4.4 ng/mL
    6200 1350 MoOx QDs detection of H2O2 and glucose H2O2 Color 10-1000 μM 7.75 μM
    6201 1350 MoOx QDs detection of H2O2 and glucose glucose Color 10-240 μM 8.95 μM
    6206 1356 PB@Ti3C2Tx Hydrogen Peroxide and Pesticide Sensing H2O2 Color 2-100,100-240 μM 0.4667 μM
    6207 1356 PB@Ti3C2Tx Hydrogen Peroxide and Pesticide Sensing Dopamine (DA) Color 5-120 μM 3.36 μM
    6208 1356 PB@Ti3C2Tx Hydrogen Peroxide and Pesticide Sensing glucose Color 10-350 μM 6.52 μM
    6209 1356 PB@Ti3C2Tx Hydrogen Peroxide and Pesticide Sensing malathion E-chem 1×10^(-15)-1×10^(-9) M 1.3×10^(-16) M
    6211 1358 Fe2.5Ti0.5O4-DES degradation of organic methylene blue Color
    6212 1359 MIONzyme cancer therapy
    6215 1362 MSF nanostructures Detection of Glucose glucose Color 1.4-86 μM 0.5 μM
    6216 1363 FePPOPEPA Colorimetric Detection for Sulfide S2- Color 0.1−10 μM 0.013 μM 102.5−106.0
    6217 1364 PPy@CoO/NiO NTs detect AA AA Color 0.5-40 μM 0.183 μM
    6218 1364 PPy@CoO/NiO NTs detect H2O2 H2O2 Color 4-60 μM 2.62 μM
    6219 1365 Fe3O4@C/Ni colorimetric assay for cholesterol determination cholesterol Color 5-200 μM 0.17 μM
    6220 1365 Fe3O4@C/Ni colorimetric assay for cholesterol determination H2O2 Color 1-50 μM 48 nM
    6225 1371 RF Resin detect glucose glucose Color 0.2-8.5 mM 9.2 μM
    6226 1371 RF Resin detect glucose H2O2 Color 0.1-2 mM 3.5 μM
    6228 1374 IONPs Iron oxide nanozyme catalyzed formation of covalently crosslinked nanogel.
    6234 1380 GI-Au NZ effectively prevent serial passage-induced senescence in nHDFs, as well as oxidative stress in mice skin, suggesting a range of strategies to further develop novel therapeutics for acute frailty
    6237 1384 CoxOyHz@ZIF-67 glucose determination in human serum samples glucose A differential photoelectrochemical (PEC) method 0.1-1000 μM 0.03 μM
    6238 1384 CoxOyHz@ZIF-67/TiO2 NTs H2O2 determination H2O2 0.01-1000 μM 5 nM
    6239 1385 Co2+ Determination of Co2+ Co2+ Color 10-300 μM 0.4 μM
    6240 1386 PDI/CeO2 NR Detection of H2O2 H2O2 Color 10-500 μM 2.23 μM
    6241 1386 PDI/CeO2 NR Detection of AA AA Color 0.5-50 μM 0.68 μM
    6242 1388 nano-PrO1.8 Detection of trans-resveratrol trans-resveratrol Color 0.3-16 μM 0.29 μM
    6243 1389 Fe3O4@Cu/C and Fe3O4@CuO oxidative degradation of model organic dyes (MB) organic dyes (MB) Color
    6247 1397 citrate-Os NPs detection of glucose glucose Color 5-200 μM 0.4 μM 91.5-103.1
    6248 1397 citrate-Os NPs detection of pyruvic acid pyruvic acid Color 10-130 μM 0.4 μM 91.3-101.0
    6249 1398 HSA@PDA/Fe NCs detection of H2O2 H2O2 Color 0.5-100 μM 0.06 μM
    6252 1402 Hb–Cu3(PO4)2 NFs Detection of Thiamine Thiamine Fluor 0.05-50 μM 0.048 μM
    6253 1403 Au@FeP detection of Fe2+ Fe2+ Color 0.41 μM
    6254 1405 NiFe2O4–PANI Sensing Ascorbic acid Ascorbic acid (AA) Color 10-100 μM 232 nM
    6255 1405 NiFe2O4–PANI Sensing Ascorbic acid Ascorbic acid (AA) E-chem 0.1-1 μM 423 nM
    6256 1405 NiFe2O4–PANI Sensing H2O2 Color 132 nM
    6257 1407 Fe3O4@C7 MNPs Detection of Uric Acid Uric Acid Color 5-250 μM 2.8 μM
    6258 1408 Cu-MOF detection of phosphate Phosphate Color 0.05-5 μM 20 nM
    6261 1411 CeGONRs Detection of OPs organophosphate Color 0.012-3.5 μg/mL 3.43 ng/mL
    6264 1414 Cu-Ag/g-C3N4/ZIF H2O2 detection H2O2 Color 0.05-1 mM 2 μM
    6265 1414 Cu-Ag/g-C3N4/ZIF Glucose detection Glucose Color 0.1-2000 μM 10 nM
    6267 1417 Au@SiO2@Fe3O4@SiO2 microspheres GSH detection GSH Color 37.5-325 and 325-3300 μM The GSH concentration was also determined in human serum
    6268 1418 Fe3O4@Poly(L-/D-Trp) Nanozymes were used to selectively label live yeast cells among yeast, S. aureus, E. coli and B. subtilis bacterial cells
    6274 1424 MoS2-Au@Pt Detection of Cys cysteine 4.8-38.4 μM 0.7 μM
    6275 1427 Cu-CuFe2O4 Colorimetric detection of H2O2 H2O2 1.7-60 μM 0.59 μM
    6276 1427 Cu-CuFe2O4 Colorimetric detection of GSH GSH 2.5-10 μM 0.31 μM
    6277 1428 WBLCS-TA For detecting cysteine Cystein Fluor 0.03 to 125 μM 1 nM
    6278 1428 WBLCS-TA-Cys For detecting Ag+ Ag+ Fluor 50-75000 nM 5 nM
    6280 1430 Pd-Pt Detection of Ascorbic acid Ascorbic acid (AA) Color 1–15 μM 0.40 μM
    6282 1433 Casein-CuS Glucose sensing Glucose Color 0.083 to 750 μM 0.005 μM
    6283 1434 Au-CDs Colorimetric monitoring of Hg2+ Hg2+ Color 7–150 nM 3.7 nM
    6285 1436 Ag@PANI To detect saccharides SERS 100 nM
    6286 1437 CHI-MoSe2-220 For the detection of H2O2 and glucose in human serum. Glucose Color 5-60 μM 0.71 μM
    6287 1437 CHI-MoSe2-220 For the detection of H2O2 and glucose in human serum. H2O2 Color 5-100 μM 0.52 μM
    6288 1439 GOx & AuNCs@ZIF-8) Colorimetric sensor for glucose Glucose Color 1.0–25.0 μM 0.8 μM
    6289 1440 Fe3O4 mesocrystals Cancer Therapy
    6290 1441 CeO2 Octa. Detection of H2O2 H2O2 Color 2-10 μM 2.569 μM
    6291 1441 CeO2 Octa. Glucose detection Glucose Color 2-10 μM 3.557 μM
    6292 1441 CeO2-Cube Detection of H2O2 H2O2 Color 1-50 μM 0.542 μM
    6293 1441 CeO2-Cube Glucose detection Glucose Color 1-100 μM 0.904 μM
    6294 1443 hPBNCs–ATP detection of alkaline phosphatase Alkaline phosphatase (ALP) Color 2.5-50 mU/mL 1.54 mU/mL 97.68%- 105.40% By utilizing the hPBNCs–ATP-based colorimetric assay, the recoveries of ALP in serum samples were in the range of 97.68% to 105.40% with the relative standard deviations (RSD, n = 3) from 2.13% to 3.22% (Table 2).
    6300 1455 IrOx Anti-tumor
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