Молекулярно импринтированные полимеры для пенициллинов и тетрациклинов

Проведён анализ описанных в литературе молекулярно импринтированных полимеров (МИП) для пенициллинов и тетрациклинов, чтобы оценить возможность использования МИП для сорбционного выделения этих антибиотиков.

молекулярно импринтированные полимеры, биосинтетические пенициллины и тетрациклины, сорбционное выделение

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46. Заявка КНР 101397163. Method for directly purifying tetracycline in water-containing sample by using molecularly imprinted polymer. 2009.

47. Заявка КНР 101402706. Method for preparing tetracycline molecular imprinted polymer used for water environment. 2009.

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60. Morais E.C., Correa G.G., Brambilla R. et al. Selective silica-based sorbent materials synthesized by molecular imprinting for adsorption of pharmaceuticals in aqueous matrices. J Separ Sci 2013; 36: 636-643.

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63. Заявка КНР 101672820. Thermal polymerization preparation method of tetracycline molecular imprinted polymer membrane electrode. 2010.

64. Заявка КНР 201965114. Instrument for detecting tetracycline concentration in water. 2011.

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69. Заявка КНР 102116758. Tetracycline drug selective electrode and preparation method thereof. 2011.

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79. Chen Z.-Q., Li J.-P., Li Y.-P. A strategy for constructing sensitive and renewable molecular imprinted carbon paste sensor. Chin J Anal Chem 2011; 39: 1009-1014.

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82. Li J., Li Y., Zhang Y., Wei G. Highly sensitive molecularly imprinted electrochemical sensor based on the double amplification by an inorganic Prussian blue catalytic polymer and the enzymatic effect of glucose oxidase. Anal Chem 2012; 84: 1888-1893.

83. Заявка КНР 102621216. Method for detecting trace oxytetracycline with double-amplification-effect molecular imprinting electrochemical sensor. 2012.

84. Wang L.-Q, Lin F.-Y., Yu L.-P. A molecularly imprinted photonic polymer sensor with high selectivity for tetracyclines analysis in food. Analyst 2012; 137: 3502-3509.

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88. Wang H., Wu X., Zhao H., Quan X. Enhanced photocatalytic degradation of tetracycline hydrochloride by molecular imprinted film modified TiO2 nanotubes. Chin Sci Bull 2012; 57: 601-605.

89. Jing T., Wang Y., Dai Q. et al. Preparation of mixed-templates molecularly imprinted polymers and investigation of the recognition ability for tetracycline antibiotics. Biosens Bioelectron 2010; 25: 2218-2224.

90. Jing T., Niu J., Xia H. et al. Online coupling of molecularly imprinted solid-phase extraction to HPLC for determination of trace tetracycline antibiotic residues in egg samples. J Separ Sci 2011; 34: 1469-1476.

91. Заявка КНР 101857664. Preparation method of molecular imprinted polymer with specific recognition capability to tetracycline family. 2010.

92. Gong G., Jia L., Li H., Qi X. Preparation and characterization of molecular imprinted polymers of tetracycline antibiotics by mixed-templates. Appl Mech Mater 2012; 128-129: 407-410.

93. Kong J., Wang Y., Nie C. et al. Preparation of magnetic mixed-templates molecularly imprinted polymer for the separation of tetracycline antibiotics from egg and honey samples. Anal Methods 2012; 4: 1005-1011.

94. Заявка КНР 101650335. Molecularly imprinted membrane detecting device for tetracycline and preparation and detection methods thereof. 2010.

95. Заявка КНР 101397355. Method for preparing molecular imprinted polymer capable of identifying oxytetracycline and enrofloxacin. 2009.