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Analytical Letters Volume 51, 2018 - Issue 11
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FLUORESCENCE

Label-Free and Simple G-quadruplex-based Turn-Off Fluorescence Assay for the Detection of Kanamycin

Yuqing ZhuSchool of Chemistry and Biological Engineering, Changsha University of Science and Technology, Changsha, ChinaView further author information
,
Wei LiSchool of Chemistry and Biological Engineering, Changsha University of Science and Technology, Changsha, ChinaCorrespondence[email protected]
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,
Shuzhen TanSchool of Chemistry and Biological Engineering, Changsha University of Science and Technology, Changsha, ChinaCorrespondence[email protected]
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&
Tianxiao ChenSchool of Chemistry and Biological Engineering, Changsha University of Science and Technology, Changsha, ChinaView further author information
Pages 1718-1729 | Received 11 Aug 2017, Accepted 28 Sep 2017, Published online: 26 Mar 2018

References

  • Aghdam, E. M., M. S. Hejazi, and A. Barzegar. 2016. Riboswitches: From living biosensors to novel targets of antibiotics. Gene 592:244–259.
  • Althaus, R., M. I. Berruga, A. Montero, M. Roca, and M. P. Molina. 2009. Evaluation of a microbiological multi-residue system on the detection of antibacterial substances in ewe milk. Analytica Chimica Acta 632:156–162.
  • Amdursky N., Y. Erez, and H. Dan. 2012. Molecular rotors: What lies behind the high sensitivity of the Thioflavin-T fluorescent marker. Accounts of Chemical Research 45 (9):1548–57.
  • Blanchaert, B., E. P. Jorge, P. Jankovics, E. Adams, and V. S. Ann. 2013. Assay of Kanamycin A by HPLC with direct UV detection. Chromatographia 76:1505–1512.
  • Chang, M. J., M. Escobedo, D. C. Anderson, L. Hillman, and R. D. Feigin. 1975. Kanamycin and gentamicin treatment of neonatal sepsis and meningitis. Pediatrics 56 (5):695–9.
  • Charles, M. H., A. W. Robert, K. M. Glen, and L. M. Brenda. 1996. Sensitive developmental periods for kanamycin ototoxic effects on distortion-product otoacoustic emissions. Hearing Reseach 98:93–103.
  • Chen, J., Z. Li, J. Ge, R. Yang, and L. Zhang. 2015. An aptamer-based signal-on bio-assay for sensitive and selective detection of Kanamycin A by using gold nanoparticles. Talanta 139:226.
  • Chen, S. H., Y. C. Liang, and Y. W. Chou. 2006. Analysis of kanamycin A in human plasma and in oral dosage form by derivatization with 1-naphthyl isothiocyanate and high-performance liquid chromatography. Journal of separation science 29 (5):607–612.
  • Chen, T. X., F. Ning, H. S. Liu, K. F. Wu, W. Li, and C. B. Ma. 2017. Label-free fluorescent strategy for sensitive detection of tetracycline based on triple-helix molecular switch and G-quadruplex. Chinese Chemical Letters 28:1380.
  • Chen, Y., Z. Wang, Z. Wang, S. Tang, and Y. Zhu. 2008. Rapid enzyme linked immunosorbent assay and colloidal gold immunoassay for kanamycin and tobramycin in Swine tissues. Journal of Agricultural Food Chemistry 56:2944–2952.
  • Davies, J., and B. D. Davis. 1968. Misreading of ribonucleic acid code words induced by aminoglycoside antibiotics: The effect of drug concentration. Journal of Biological Chemietry 243:3312–3316.
  • El-Attug, M. N., E. Adams, J. Hoogmartens, and A. V. Schepdael. 2011. Capacitively coupled contactless conductivity detection as an alternative detection mode in CE for the analysis of kanamycin sulphage and its related substances. Journal of Separation Science 34:2448–2454.
  • Ellington, A. D., and J. W. Szostak. 1990. In vitro selection of RNA molecules that bind specific ligands. Nature 346:818–822.
  • Frasconi, M., R. Tel-Vered, M. Riskin, and I. Willner. 2010. Surface plasmon resonance analysis of antibiotics using imprinted boronic acid-functionalized Au nanoparticle composites. Analytical Chemistry 82:2512–2519.
  • Fernando, H., R. Rodriguez, and S. Balasubramanian. 2008. Selective recognition of a DNA G-Quadruplex by an engineered antibody. Biochemistry 47:9365–9371.
  • Fujita, H., Y. Imaizumi, Y. Kasahara, S. Kitadume, and H. Ozaki. 2013. Structural and affinity analyses of G-Quadruplex DNA aptamers for camptothecin derivatives. Pharmaceuticals 6:1082–1093.
  • Ha, N. R., I. P. Jung, I. J. La, H. S. Jung, and M. Y. Yoon. 2017. Ultra-sensitive detection of kanamycin for food safety using a reduced graphene oxide-based fluorescent aptasensor. Scientific Reports 7:40305.
  • He, J. X., Y. Wang, and X. Y. Zhang. 2016. Preparation of artificial antigen and development of IgY-based indirect competitive ELISA for the detection of kanamycin residues. Food Analytical Methods 9 (3):744–51.
  • Imaizumi, Y., Y. Kasahara, and H. Fujita. 2013. Efficacy of base-modification on target binding of small molecule DNA aptamers. Journal of the American Chemical Society 135 (25):9412–9419.
  • Isoherranen, N., and S. Soback. 1999. Chromatographic methods for analysis of aminoglycoside antibiotics. Journal of AOAC International 82:1017–1045.
  • Jin, Y., J. W. Jang, C. H. Han, and M. H. Lee. 2006. Development of immunoassays for the detection of kanamycin in veterinary fields. Journal of Veterinary Science 7 (2):111–117.
  • Kataoka, Y., H. Fujita, Y. Kasahara, T. Yoshihara, and S. Tobita. 2014. Minimal Thioflavin T modifications improve visual discrimination of guanine-quadruplex topologies and alter compound-induced topological structures. Analytical Chemistry 86 (24):12078.
  • Liao, Q. G., B. H. Wei, and L. G. Luo. 2017. Aptamer based fluorometric determination of kanamycin using double-stranded DNA and carbon nanotubes. Microchimica Acta 184 (2):627–632.
  • Liu, R., Z. Yang, Q. Guo, J. Zhao, J. Ma, Q. Kang, and Y. Tang. 2015. Signaling-probe displacement electrochemical aptamer-based sensor (SD-EAB) for detection of nanomolar Kanamycin A. Electrochimica Acta 182:516–523.
  • Long, Y. H., M. Hernandez, E. Kaale, A. V. Schepdael, E. Roets, F. Borrull, M. Calull, and J. Hoogmartens. 2003. Determination of kanamycin in serum by solid-phase extraction, pre-capillary derivatization and capillary electrophoresis. Journal of Chromatography B784:255–264.
  • Meng, H. M., H. Liu, H. L. Kuai, and X. B. Zhang. 2016. Aptamer-integrated DNA nanostructures for biosensing, bioimaging and cancer therapy. Chemical Society Reviews 45:2583–2602.
  • Mohanty, J., N. Barooah, V. Dhamodharan, and S. Harikrishna. 2013. Thioflavin T as an efficient inducer and selective fluorescent sensor for the human telomericG-quadruplex DNA. Journal of the American Chemical Society 135:367–376.
  • Oertel, R., V. Neumeister, and W. Kirch. 2004. Hydrophilic interaction chromatography combined with tandem-mass spectrometry to determine six aminoglycosides in serum. Journal of Chromatography A1058:197–201.
  • O’neal, J. S., and S. G. Schulman. 1984. Fluorescence polarization immunoassay of Kanamycin. Analytical letters 17 (14):1627–1635.
  • Ouyang, X., R. Yu, J. Jin, J. Li, R. Yang, W. Tan, and J. Yuan. 2011. New Strategy for Label-Free and Time-Resolved Luminescent Assay of Protein: Conjugate Eu3+ Complex and Aptamer-Wrapped Carbon Nanotubes. Analytical Chemistry 83:782–789.
  • Patel, K. N., R. S. Limgavkar, H. G. Raval, K. G. Patel, and T. R. Gandhi. 2015. High performance liquid chromatographic determination of cefalexin monohydrate and kanamycin monosulfate with precolumn derivatization. Journal of Liquid Chromatography Related Technologies 38 (6):716–21.
  • Song, K. M., M. Cho, H. Jo, K. Min, and S. H. Jeon. 2011. Gold nanoparticle-based colorimetric detection of kanamycin using a DNA aptamer. Analytical Biochemistry 415:175–181.
  • Sulatskaya, A. I., A. A. Maskevich, I. M. Kuznetsova, V. N. Uversky, and K. K. Turoverov. 2010. Fluorescence quantum yield of thioflavin T in rigid isotropic solution and incorporated into the amyloid fibrils. Plos One 5 (10):e15385.
  • Tan, W. H., M. J. Donovan, and J. H. Jiang. 2013. Aptamers from cell-based selection for bioanalytical applications. Chemical Reviews 113:2842–2862.
  • Tong, L., L. Li, Z. Chen, Q. Wang, and B. Tang. 2013. Stable label-free fluorescent sensing of biothiols based on Thioflavin T direct inducing conformation-specific G-quadruplex. Biosensors and Bioelectronics 49 (11):420.
  • Tuerk, C., and L. Gold. 1990. Systematic evolution of ligands by exponential enrichment: RNA ligands to bacteriophage T4 DNA polymerase. Science 249:505–510.
  • Wang, X., M. Zou, X. Xu, R. Lei, and K. Li. 2009. Determination of human urinary kanamycin in one step using urea-enhanced surface plasmon resonance lightscattering of gold nanoparticles. Analytical Bioanalytical Chemistry 395:2397–2403.
  • Wang, C., D. Chen, Q. Wang, and R. Tan. 2017. Kanamycin detection based on the catalytic ability enhancement of gold nanoparticles. Biosensors and Bioelectronics 91:262.
  • Wang, C., C. Liu, J. Luo, Y. Tian, and N. Zhou. 2016. Direct electrochemical detection of kanamycin based on peroxidase-like activity of gold nanoparticles. Analytica Chimica Acta 936:75.
  • Wen, Y., L. Wang, L. Li, L. Xu, and G. Liu. 2016. A Sensitive and label-free Pb(II) fluorescence sensor based on a DNAzyme controlled G-quadruplex/thioflavin T conformation. Sensors 16 (12):2155.
  • Xing, Y. P., C. Liu, X. H. Zhou, and H. C. Shi. 2015. Label-free detection of kanamycin based on a G-quadruplex DNA aptamer-based fluorescent intercalator displacement assay. Scientific Reports 5:8125.
  • Xu, W., Y. Wang, S. Liu, J. H. Yu, H. Z. Wang, and J. D. Huang. 2014. A novel sandwich-type electrochemical aptasensor for sensitive detection of kanamycin based on GR–PANI and PAMAM–Au nanocomposites. New Journal of Chemistry 38:4931.
  • Yaku, H., T. Fujimoto, T. Murashima, D. Miyoshi, and N. Sugimoto. 2012. Phthalocyanines: A new class of G-quadruplex-ligands with many potential applications. Chemical Communications 48:6203–6216.
  • Yoshizawa, S., D. Fourmy, and J. D. Puglisi. 1998. Structural origins of gentamicin antibiotic action. The EMBO journal 17:6437–6448.
  • Zhu, Y., P. Chandra, K. M. Song, C. Ban, and Y. B. Shim. 2012. Label-free detection of kanamycin based on the aptamer-functionalized conducting polymer/gold nanocomposite. Biosensors and Bioelectronics 36:29–34.

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