Aptamer-based fluorescence-quenching lateral flow strip for rapid detection of mercury (II) ion in water samples

被引:0
作者
Ze Wu
Haicong Shen
Junhui Hu
Qiangqiang Fu
Cuize Yao
Shiting Yu
Wei Xiao
Yong Tang
机构
[1] Jinan University,Department of Bioengineering, Guangdong Province Key Laboratory of Molecular Immunology and Antibody Engineering
[2] Jinan University,Institute of Biotranslational Medicine
来源
Analytical and Bioanalytical Chemistry | 2017年 / 409卷
关键词
Aptamer; Lateral flow strip; Fluorescence-quenching; Low-background; Mercury (II) ions;
D O I
暂无
中图分类号
学科分类号
摘要
Divalent mercury ion (Hg2+) is one of the most common and stable forms of mercury pollution. In this study, a skillfully designed lateral flow strip (LFS) was developed for sensitive detection of Hg2+ in river water samples. Aptamer, a specific oligonucleotide probe, was used to selectively identify and target Hg2+ instead of antibody in traditional immunechromatographic strips; and the fluorescence-quenching system was used to generate positive and low background florescence signals in the competitive-likely LFS. The linear detection range of the LFS for Hg2+ was 0.13 ng mL–1 to 4 ng mL–1 and the limit of detection (LOD) was 0.13 ng mL–1. This test provided results in 15 min and demonstrated high specificity. For detection of Hg2+ in river water, the results were consistent with inductively coupled plasma-mass spectrometry measurements. The aptamer-based fluorescence-quenching LFS was shown to provide a reliable, accurate method for rapid detection of mercury contamination.
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页码:5209 / 5216
页数:7
相关论文
共 156 条
[1]  
Miller JR(1996)Dispersal of mercury-contaminated sediments by geomorphic processes, Sixmile Canyon, Nevada, USA: implications to site characterization and remediation of fluvial environments Water Air Soil Pollut 86 373-88
[2]  
Rowland J(2013)Mechanisms regulating mercury bioavailability for methylating microorganisms in the aquatic environment: a critical review Environ Sci Technol 47 2441-24456
[3]  
Lechler PJ(1998)Effects of mercury on wildlife: a comprehensive review Environ Toxicol Chem 17 146-60
[4]  
Desilets M(1997)The toxicology of mercury Crit Rev Clin Lab Sci 34 369-403
[5]  
Hsu L-C(2016)Mercury contamination in the blood, urine, hair, and nails of the gold washers and its human health risk during extraction of placer gold along Gilgit, Hunza, and Indus rivers in Gilgit-Baltistan, Pakistan Environ Technol Innov 5 22-9
[6]  
Hsu-Kim H(2015)A highly selective and simple fluorescent sensor for mercury (II) ion detection based on cysteamine‐capped CdTe quantum dots synthesized by the reflux method Lumin 30 465-71
[7]  
Kucharzyk KH(2013)Methylmercury production below the mixed layer in the North Pacific Ocean Nat Geosci 6 879-84
[8]  
Zhang T(2009)Stress proteins and oxidative damage in a renal derived cell line exposed to inorganic mercury and lead Toxicolgy 264 215-24
[9]  
Deshusses MA(2010)Ochratoxin A: general overview and actual molecular status Toxins 2 461-93
[10]  
Wolfe MF(2011)Recent trends in macro-, micro-, and nanomaterial-based tools and strategies for heavy-metal detection Chem Rev 111 3433-58
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