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PUBMED FOR HANDHELDS

Journal Abstract Search


386 related items for PubMed ID: 28411826

  • 21. Detection of DNA 3'-phosphatase activity based on exonuclease III-assisted cascade recycling amplification reaction.
    Zhang Y, Wang Y, Rizvi SFA, Zhang Y, Zhang Y, Liu X, Zhang H.
    Talanta; 2019 Nov 01; 204():499-506. PubMed ID: 31357325
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  • 22. A versatile and highly sensitive homogeneous electrochemical strategy based on the split aptamer binding-induced DNA three-way junction and exonuclease III-assisted target recycling.
    Hou T, Li W, Zhang L, Li F.
    Analyst; 2015 Aug 21; 140(16):5748-53. PubMed ID: 26165638
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  • 23. Nicking endonuclease-assisted recycling of target-aptamer complex for sensitive electrochemical detection of adenosine triphosphate.
    Hu T, Wen W, Zhang X, Wang S.
    Analyst; 2016 Feb 21; 141(4):1506-11. PubMed ID: 26815141
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  • 24. Enzymatic cleavage and mass amplification strategy for small molecule detection using aptamer-based fluorescence polarization biosensor.
    Kang L, Yang B, Zhang X, Cui L, Meng H, Mei L, Wu C, Ren S, Tan W.
    Anal Chim Acta; 2015 Jun 16; 879():91-6. PubMed ID: 26002482
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  • 25. A nuclease-assisted label-free aptasensor for fluorescence turn-on detection of ATP based on the in situ formation of copper nanoparticles.
    Song Q, Wang R, Sun F, Chen H, Wang Z, Na N, Ouyang J.
    Biosens Bioelectron; 2017 Jan 15; 87():760-763. PubMed ID: 27649332
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  • 26. An ultrasensitive fluorescent aptasensor for adenosine detection based on exonuclease III assisted signal amplification.
    Hu P, Zhu C, Jin L, Dong S.
    Biosens Bioelectron; 2012 Apr 15; 34(1):83-7. PubMed ID: 22382074
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  • 27. A target responsive aptamer machine for label-free and sensitive non-enzymatic recycling amplification detection of ATP.
    Li X, Peng Y, Chai Y, Yuan R, Xiang Y.
    Chem Commun (Camb); 2016 Mar 04; 52(18):3673-6. PubMed ID: 26853492
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  • 28. A catalytic and dual recycling amplification ATP sensor based on target-driven allosteric structure switching of aptamer beacons.
    Peng Y, Li D, Yuan R, Xiang Y.
    Biosens Bioelectron; 2018 May 15; 105():1-5. PubMed ID: 29331900
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  • 29. A magnified aptamer fluorescence sensor based on the metal organic frameworks adsorbed DNA with enzyme catalysis amplification for ultra-sensitive determination of ATP and its logic gate operation.
    Yao J, Yue T, Huang C, Wang H.
    Bioorg Chem; 2021 Sep 15; 114():105020. PubMed ID: 34328850
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  • 30. A facile aptasensor based on polydopamine nanospheres for high-sensitivity sensing of T-2 toxin.
    Guo T, Wang C, Zhou H, Zhang Y, Ma L, Wang S.
    Anal Methods; 2021 Jun 24; 13(24):2654-2658. PubMed ID: 34036989
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  • 31. A highly sensitive fluorescence biosensor for aflatoxins B1 detection based on polydiacetylene liposomes combined with exonuclease III-assisted recycling amplification.
    Tao C, Wang J, Zhu Y, Ding C, Shen Z, Sun D, Cao S, Jiang X, Li Y, Liu C, Zhang Q, Li S, Zhang X, Shi Q, Kong D.
    Mikrochim Acta; 2024 Jun 14; 191(7):397. PubMed ID: 38877314
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  • 32. A highly sensitive and selective fluorescence biosensor for hepatitis C virus DNA detection based on δ-FeOOH and exonuclease III-assisted signal amplification.
    Wu T, Li X, Fu Y, Ding X, Li Z, Zhu G, Fan J.
    Talanta; 2020 Mar 01; 209():120550. PubMed ID: 31891998
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  • 33. Amplified fluorescent aptasensor through catalytic recycling for highly sensitive detection of ochratoxin A.
    Wei Y, Zhang J, Wang X, Duan Y.
    Biosens Bioelectron; 2015 Mar 15; 65():16-22. PubMed ID: 25461133
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  • 34. A AuNP-capped cage fluorescent biosensor based on controlled-release and cyclic enzymatic amplification for ultrasensitive detection of ATP.
    Wang W, Li X, Tang K, Song Z, Luo X.
    J Mater Chem B; 2020 Jul 15; 8(27):5945-5951. PubMed ID: 32667018
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  • 35. Highly sensitive fluorescence detection of target DNA by coupling exonuclease-assisted cascade target recycling and DNAzyme amplification.
    Liu S, Cheng C, Liu T, Wang L, Gong H, Li F.
    Biosens Bioelectron; 2015 Jan 15; 63():99-104. PubMed ID: 25063920
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  • 36. A label-free fluorescence assay for thrombin based on aptamer exonuclease protection and exonuclease III-assisted recycling amplification-responsive cascade zinc(II)-protoporphyrin IX/G-quadruplex supramolecular fluorescent labels.
    Lv Y, Xue Q, Gu X, Zhang S, Liu J.
    Analyst; 2014 May 21; 139(10):2583-8. PubMed ID: 24707508
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  • 37. A Label-free and Turn-on Fluorescence Strategy for DNA Detection with a Wide Detection Range Based on Exonuclease III-aided Target Recycling Amplification.
    Yang H, Song X, Ding B, Li Z, Zhang X.
    Anal Sci; 2017 May 21; 33(1):9-11. PubMed ID: 28070084
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  • 38. Exonuclease III-Assisted Target Recycling Amplification Coupled with Liposome-Assisted Amplification: One-Step and Dual-Amplification Strategy for Highly Sensitive Fluorescence Detection of DNA.
    Zhou F, Li B.
    Anal Chem; 2015 Jul 21; 87(14):7156-62. PubMed ID: 26111123
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  • 39. Fluorometric aptamer assay for ochratoxin A based on the use of single walled carbon nanohorns and exonuclease III-aided amplification.
    Wu H, Liu R, Kang X, Liang C, Lv L, Guo Z.
    Mikrochim Acta; 2017 Dec 06; 185(1):27. PubMed ID: 29594393
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  • 40. Ultrasensitive fluorescence detection of nucleic acids using exonuclease III-induced cascade two-stage isothermal amplification-mediated zinc (II)-protoporphyrin IX/G-quadruplex supramolecular fluorescent nanotags.
    Xue Q, Lv Y, Zhang Y, Xu S, Li R, Yue Q, Li H, Wang L, Gu X, Zhang S, Liu J.
    Biosens Bioelectron; 2014 Nov 15; 61():351-6. PubMed ID: 24912035
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