Improving sensitivity of gold nanoparticle based fluorescence quenching and colorimetric aptasensor by using water resuspended gold nanoparticle

文献类型: 外文期刊

第一作者: Liu, Jinchuan

作者: Liu, Jinchuan;Guan, Zheng;Lv, Zhenzhen;Jiang, Xiaoling;Yang, Shuming;Chen, Ailiang;Liu, Jinchuan;Guan, Zheng;Lv, Zhenzhen;Jiang, Xiaoling;Yang, Shuming;Chen, Ailiang

作者机构:

关键词: Gold nanoparticle;Fluorescence quenching;Colorimetry;Aptamer;Sulfadimethoxine;Thrombin

期刊名称:BIOSENSORS & BIOELECTRONICS ( 影响因子:10.618; 五年影响因子:9.323 )

ISSN:

年卷期:

页码:

收录情况: SCI

摘要: Gold nanoparticles (AuNPs) based fluorescence quenching or colorimetric aptasensor have been developed for many analytes recently largely because of the ease of detection, high sensitivity, and potential for high-throughput analysis. However, the effects of remnant non-AuNPs components in the colloid gold solution on these assays performance remain unclear. For the first time, we demonstrated that the remnant sodium citrate and the reaction products of three acids play counteractive roles in AuNPs based fluorescence quenching and colorimetric aptasensor in three ways in this study. First, the remnant sodium citrate in the colloid gold solution could increase the fluorescence intensity of FAM labeled on the aptamer that reduce the efficiency of AuNPs fluorescent quenching. Second, the reaction products of citric acid, HC1 and ketoglutaric acid reduce the fluorescence recovery by quenching the fluorescence of FAM labeled on the aptamer dissociated from the surface of AuNPs upon addition of target. Lastly, the reaction products of three acids reduce the pH value of the colloid gold solution that reduce the sensitivity of AuNPs based colorimetric aptasensor by increasing the adsorption of aptamer to surface of AuNPs. With sulfadimethoxine and thrombin as model analytes, we found that water resuspended AuNPs can significantly increase the sensitivity by more than 10-fold for AuNPs based fluorescence quenching aptasensor. In the AuNPs based colorimetric aptasensor for sulfadimethoxine using the water resuspended AuNPs, the sensitivity also was increased by 10-fold compared with that of original AuNPs. The findings in this study provide theoretical guidance for further improving AuNPs based fluorescent quenching and colorimetric aptasensor by adjusting the composition of AuNPs solution.

分类号: Q

  • 相关文献

[1]High sensitive rapid visual detection of sulfadimethoxine by label-free aptasensor. Chen, Ailiang,Jiang, Xiaoling,Zhang, Weiwei,Chen, Gang,Zhao, Yan,Tunio, Tarique Muhammad,Liu, Jinchuan,Lv, Zhenzhen,Yang, Shuming,Chen, Ailiang,Jiang, Xiaoling,Zhang, Weiwei,Chen, Gang,Zhao, Yan,Tunio, Tarique Muhammad,Liu, Jinchuan,Yang, Shuming,Lv, Zhenzhen,Li, Cheng.

[2]Visual and microplate detection of aflatoxin B2 based on NaCl-induced aggregation of aptamer-modified gold nanoparticles. Luan, Yunxia,Chen, Jiayi,Li, Cheng,Ping, Hua,Ma, Zhihong,Lu, Anxiang,Xie, Gang.

[3]Gold Nanoparticle-Aptamer Based Colorimetric Biosensing Assays. Liu Jin-chuan,Lu Zhen-zhen,Chen Ai-liang. 2014

[4]Gold nanoparticle-based colorimetric aptasensor for rapid detection of six organophosphorous pesticides. Bai, Wenhui,Zhu, Chao,Liu, Jinchuan,Yan, Mengmeng,Yang, Shuming,Chen, Ailiang,Bai, Wenhui,Zhu, Chao,Liu, Jinchuan,Yan, Mengmeng,Yang, Shuming,Chen, Ailiang. 2015

[5]A convenient sandwich assay of thrombin in biological media using nanoparticle-enhanced fluorescence polarization. Yue, Qiaoli,Shen, Tongfei,Wang, Lei,Xu, Shuling,Li, Haibo,Xue, Qingwang,Zhang, Yuanfu,Liu, Jifeng,Gu, Xiaohong,Zhang, Shuqiu.

[6]A simple and sensitive label-free fluorescent approach for protein detection based on a Perylene probe and aptamer. Lv, Zhenzhen,Liu, Jinchuan,Bai, Wenhui,Yang, Shuming,Chen, Ailiang,Lv, Zhenzhen,Liu, Jinchuan,Bai, Wenhui,Yang, Shuming,Chen, Ailiang,Lv, Zhenzhen.

[7]Aptamer based fluorometric determination of kanamycin using double-stranded DNA and carbon nanotubes. Liao, Qie Gen,Wei, Ben Hua,Luo, Lin Guang.

[8]Aptamer based photometric assay for the antibiotic sulfadimethoxine based on the inhibition and reactivation of the peroxidase-like activity of gold nanoparticles. Yan, Jiao,Huang, Yafei,Zhang, Chenghui,Fang, Zongzhuang,Yan, Jiao,Huang, Yafei,Bai, Wenhui,Yan, Mengmeng,Zhu, Chao,Chen, Ailiang,Yan, Jiao,Huang, Yafei,Bai, Wenhui,Yan, Mengmeng,Zhu, Chao,Chen, Ailiang.

[9]Test of hirudin activity by tracking the binding of hirudin to thrombin in the presence of BS3 cross-linking. Liu, Yanfang,Wang, Jiangmin,Huang, Qingmei,Yang, Xiaohong,Zhang, Jianhua,Yang, Jian. 2015

[10]Influence of glycosylation of deamidated wheat gliadin on its interaction mechanism with resveratrol. Qiu, Chaoying,Wang, Yong,Teng, Yinglai,Qiu, Chaoying,Zhao, Mouming.

[11]Spectrophotometric and visual detection of the herbicide atrazine by exploiting hydrogen bond-induced aggregation of melamine-modified gold nanoparticles. Liu, Guangyang,Yang, Xin,Zhang, Yanxin,Zhou, Pan,Liu, Guangyang,Li, Tengfei,Yu, Hailong,Du, Xinwei,She, Yongxin,Wang, Jing,Wang, Shanshan,Jin, Fen,Jin, Maojun,Shao, Hua,Zheng, Lufei,Liu, Guangyang,Li, Tengfei,Yu, Hailong,Du, Xinwei,She, Yongxin,Wang, Jing,Wang, Shanshan,Jin, Fen,Jin, Maojun,Shao, Hua,Zheng, Lufei.

[12]A method to label biological molecules with dsDNA coated gold nanoparticles. Xing, Ming,Dong, Yingshan,Xing, Ming,Li, Fangliang,Chen, Xia,Xing, Ming,Li, Fangliang,Chen, Xia,Yu, Zhenxiang.

[13]A gold nanoparticle based immunosorbent bio-barcode assay combined with real-time immuno-PCR for the detection of polychlorinated biphenyls. Yang, Guangxin,Zhuang, Huisheng,Chen, Hanyu,Ping, Xianyin,Bu, Dan,Yang, Guangxin,Ping, Xianyin.

[14]Fluorescence switching sensor for sensitive detection of sinapine using carbon quantum dots. Xiang, Xia,Zhang, Zhen,Han, Ling,Huang, Fenghong,Zheng, Mingming,Tang, Hu,Deng, Qianchun.

[15]Fusion expression of bovine lactoferricin in Escherichia coli. Feng, Xing-jun,Wang, Jian-hua,Shan, An-shan,Teng, Da,Yang, Ya-lin,Yao, Yi,Yang, Guan-pin,Shao, Yan-chun,Liu, Shuo,Zhang, Fan.

[16]Competitive colorimetric triazophos immunoassay employing magnetic microspheres and multi-labeled gold nanoparticles along with enzymatic signal enhancement. Du, Pengfei,Jin, Maojun,Chen, Ge,Zhang, Chan,Cui, Xueyan,Zhang, Yudan,Zhang, Yanxin,Zou, Pan,Jiang, Zejun,Cao, Xiaolin,She, Yongxin,Jin, Fen,Wang, Jing.

[17]Synthesis and optical properties of a novel sugar coated poly(p-phenyleneethynylene) effectively quenched by concanavalin A. Tsakama, Madalitso,Shang, Yuting,He, Yonghuang,Fan, Bei,Wang, Fengzhong,Chen, Weihua,Dai, Xiaofeng.

[18]A label-free and high sensitive aptamer biosensor based on hyperbranched polyester microspheres for thrombin detection. Sun, Chong,Han, Qiaorong,Wang, Weijuan,Zhao, Wenbo,Sun, Chong,Wang, Daoying,Xu, Weimin,Zhou, Min.

[19]Development of fluorescent FeIII sensor based on chalcone. Wei, Yanli,Wang, Wenyan,Bian, Wei,Shuang, Shaomin,Dong, Chuan,Qin, Guojie.

[20]Dual-competitive lateral flow aptasensor for detection of aflatoxin B-1 in food and feedstuffs. Zhu, Chao,Zhang, Guilan,Huang, Yafei,Yang, Shuming,Chen, Ailiang,Zhu, Chao,Zhang, Guilan,Huang, Yafei,Yang, Shuming,Chen, Ailiang,Huang, Yafei,Ren, Shuyue,Gao, Zhixian. 2018

作者其他论文 更多>>

微信小程序