Zhiliang Jiang scite author profile

Single-strand DNA (ssDNA) was used to modify 10 nm nanogold to obtain an aptamer-modified nanogold resonance scattering (RS) probe (AussDNA) for detection of Hg(2+). In the presence of NaCl, Hg(2+) interacts with AussDNA to form very stable double-strand T-Hg(2+)-T mismatches and release nanogold particles that aggregate to large nanogold clusters causing the RS intensity at 540 nm to be enhanced linearly. On those grounds, 1.3-1667 nM Hg(2+) can be detected rapidly by the aptamer-modified nanogold RS assay, with a detection limit of 0.7 nM Hg(2+). If the large nanogold clusters were removed by membrane filtration, the excess AussDNA in the filtrate solution exhibits a catalytic effect on the new Cu(2)O particle reaction between NH(2)OH and Cu(2+)-EDTA complex at 60 degrees C. The excess AussDNA decreased with the addition of Hg(2+), which led the Cu(2)O particle RS intensity at 602 nm to decrease. The decreased RS intensity (DeltaI(602nm)) had a linear response to Hg(2+) concentration in the range of 0.1-400 nM, with a detection limit of 0.03 nM Hg(2+). This aptamer-modified nanogold catalytic RS method was applied for the detection of Hg(2+) in water samples, with sensitivity, selectivity, and simplicity.

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Catalytic Effect of Nanogold on Cu(II)−N₂H₄ Reaction and Its Application to Resonance Scattering Immunoassay

Jiang

Liao

Deng

et al. 2008

Anal. Chem.

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In the medium of EDTA-NaOH, nanogold strongly catalyzed the slow reaction between hydrazine (N2H4) and Cu(II) to form Cu particles, which exhibited a strong resonance scattering (RS) peak at 602 nm. The increased RS intensity at 602 nm (DeltaI(RS)) was linear to the nanogold concentration in the range of 0.008-2.64 nM, with a detection limit of 1.0 pM Au. The rate equation obtained by the initial rate procedure was V(Cu) = K(Cu)[C(Cu(II))](2)C(OH)(1)C(Au)(1)C(N2)H4(1), with an apparent activation energy of 38 kJ x mol(-1), and the catalytic reaction mechanism was also discussed. An immunonanogold-catalytic resonance scattering spectral (RSS) assay was established for detection of microalbumin (Malb), using 10 nm nanogold to label goat antihuman Malb to obtain an immunonanogold probe (AuMalb) for Malb. In pH 5.0 citric acid-Na2HPO4 buffer solution, the AuMalb aggregated nonspecifically. Upon addition of Malb, it reacted with the probe to form dispersive AuMalb-Malb immunocomplex in the solution. After centrifugation, the supernatant containing AuMalb-Malb was obtained, and exhibited a catalytic effect on the reaction of N2H4-Cu(II) to produce large Cu particles that resulted in the I(602 nm) increasing. The increased RS intensity at 602 nm (DeltaI(602 nm)) was linear to Malb concentration (C(Malb)) in the range of 0.4 to 460 pg x mL(-1), with the regression equation of DeltaI(602 nm) = 0.3713 C(Malb) + 7.2, correlation coefficient of 0.9981 and detection limit of 0.1 pg x mL(-1) Malb. The proposed method was applied to detect Malb in healthy human urine samples, with satisfactory results.

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Nanosol SERS quantitative analytical method: A review

Yao

et al. 2020

TrAC Trends in Analytical Chemistry

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Resonance scattering spectroscopy of gold nanoparticle

Jiang

Feng

et al. 2001

Sc. China Ser. B-Chem.

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A new silver nanorod SPR probe for detection of trace benzoyl peroxide

Jiang

Wen

Luo

et al. 2014

Sci Rep

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The stable silver nanorod (AgNR) sol in red was prepared by the two-step procedure of NaBH4-H2O2 and citrate heating reduction. The AgNR had a transverse and a longitudinal surface plasmon resonance (SPR) absorption peak at 338 nm and 480 nm. Meanwhile, two transverse and longitudinal SPR Rayleigh scattering (SPR-RS) peaks at 340 nm and 500 nm were observed firstly using common fluorescence spectrometer. The SPR absorption, RS, surface enhanced Raman scattering (SERS) and electron microscope technology were used to study the formation mechanism of red silver nanorods and the SERS enhancement mechanism of nano-aggregation. The AgNR-BPO SPR absorption and AgNR-NaCl-BPO SPR-RS analytical systems were studied to develop two new simple, rapid, and low-cost SPR methods for the detection of trace BPO.

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Resonance scattering detection of trace melamine using aptamer-modified nanosilver probe as catalyst without separation of its aggregations

2011

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Gold-Labeled Nanoparticle-Based Immunoresonance Scattering Spectral Assay for Trace Apolipoprotein AI and Apolipoprotein B

Jiang

Sun

Liang

et al. 2006

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Zhiliang Jiang

The surface-plasmon-resonance effect of nanogold/silver and its analytical applications

Resonance Scattering Spectral Detection of Trace Hg²⁺ Using Aptamer-Modified Nanogold as Probe and Nanocatalyst

Catalytic Effect of Nanogold on Cu(II)−N₂H₄ Reaction and Its Application to Resonance Scattering Immunoassay

Nanosol SERS quantitative analytical method: A review

Resonance scattering spectroscopy of gold nanoparticle

A new silver nanorod SPR probe for detection of trace benzoyl peroxide

Resonance scattering detection of trace melamine using aptamer-modified nanosilver probe as catalyst without separation of its aggregations

Gold-Labeled Nanoparticle-Based Immunoresonance Scattering Spectral Assay for Trace Apolipoprotein AI and Apolipoprotein B

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Zhiliang Jiang

The surface-plasmon-resonance effect of nanogold/silver and its analytical applications

Resonance Scattering Spectral Detection of Trace Hg2+ Using Aptamer-Modified Nanogold as Probe and Nanocatalyst

Catalytic Effect of Nanogold on Cu(II)−N2H4 Reaction and Its Application to Resonance Scattering Immunoassay

Nanosol SERS quantitative analytical method: A review

Resonance scattering spectroscopy of gold nanoparticle

A new silver nanorod SPR probe for detection of trace benzoyl peroxide

Resonance scattering detection of trace melamine using aptamer-modified nanosilver probe as catalyst without separation of its aggregations

Gold-Labeled Nanoparticle-Based Immunoresonance Scattering Spectral Assay for Trace Apolipoprotein AI and Apolipoprotein B

Contact Info

Product

Resources

About

Resonance Scattering Spectral Detection of Trace Hg²⁺ Using Aptamer-Modified Nanogold as Probe and Nanocatalyst

Catalytic Effect of Nanogold on Cu(II)−N₂H₄ Reaction and Its Application to Resonance Scattering Immunoassay