Abstract:
Characteristic features of the synthesis of molecularly imprinted polymer systems used as sorbents for separation of complex mixtures into components are discussed. The data about the molecules imprinted in monoliths of various natures and shapes are integrated. Examples of application of new-generation separating media are discussed. Data on the utilization of the molecular imprinting principle for the fabrication of supermacroporous monolithic cryogels specific to particular molecules, which is important for the design of smart biomaterials, are analyzed.
The bibliography includes 293 references.
Received: 17.09.2014
Bibliographic databases:
Language: English
Original paper language: Russian
Citation:
E. G. Vlakh, V. A. Korzhikov, A. V. Hubina, T. B. Tennikova, “Molecular imprinting: a tool of modern chemistry for the preparation of highly selective monolithic sorbents”, Russian Chem. Reviews, 84:9 (2015), 952–980
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\by E.~G.~Vlakh, V.~A.~Korzhikov, A.~V.~Hubina, T.~B.~Tennikova
\paper Molecular imprinting: a~tool of modern chemistry for the preparation of highly selective monolithic sorbents
\jour Russian Chem. Reviews
\yr 2015
\vol 84
\issue 9
\pages 952--980
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\crossref{https://doi.org/10.1070/RCR4501}
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Linking options:
https://www.mathnet.ru/eng/rcr4068
https://doi.org/10.1070/RCR4501
https://www.mathnet.ru/eng/rcr/v84/i9/p952
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M. S. Leonovich, V. A. Korzhikov-Vlakh, E. G. Korzhikova-Vlakh, I. A. Guryanov, O. N. Brevnov, T. B. Tennikova, Polymer Science, Series A, 66:1 (2024), 23
Antipchik M., Dzhuzha A., Sirotov V., Tennikova T., Korzhikova-Vlakh E., J. Appl. Polym. Sci., 138:12 (2021), e50070, 50070
Kurmaz V S. Fadeeva V N. Gorshkova I A. Kurochkin S.A. Knerelman I E. Davydova I G. Torbov I V. Dremova N.N. Konev V D. Kurmaz V.A. Ignatiev V.M. Emelyanova N.S., Materials, 14:22 (2021), 6757
Zare E.N., Mudhoo A., Khan M.A., Otero M., Bundhoo Zumar Muhammad Ali, Patel M., Srivastava A., Navarathna Ch., Mlsna T., Mohan D., Pittman Jr. Charles U., Makvandi P., Sillanpaa M., Small, 17:34 (2021), 2007840, 2007840
Korzhikova-Vlakh E., Antipchik M., Tennikova T., Polymers, 13:7 (2021), 1059
V. I. Lozinsky, Gels, 6:3 (2020), 29
I. I. Kurochkin, I. N. Kurochkin, O. Yu. Kolosova, V. I. Lozinsky, Molecules, 25:19 (2020), 4480
M. Stepanova, O. Solomakha, D. Ten, T. Tennikova, E. Korzhikova-Vlakh, Catalysts, 10:12 (2020), 1395
O. Erdem, Y. Saylan, N. Cihangir, A. Denizli, Biosens. Bioelectron., 126 (2019), 608–614
Xiao X. Li Zh. Liu Ya. Jia L., J. Sep. Sci., 42:23 (2019), 3544–3552
S. V. Kurmaz, N. V. Fadeeva, E. I. Knerel'man, G. I. Davydova, Polym. Sci. Ser. B, 60:2 (2018), 195–203
S. V. Kurmaz, N. V. Fadeeva, E. I. Knerel'man, G. I. Davydova, Russ. J. Appl. Chem., 91:1 (2018), 105–112
M. A. Stepanova, L. R. Kinziabulatova, A. A. Nikitina, E. G. Korzhikova-Vlakh, T. B. Tennikova, Electrophoresis, 38:22-23, SI (2017), 2965–2974
N. V. Fadeeva, S. V. Kurmaz, E. I. Knerel'man, G. I. Davydova, V. I. Torbov, N. N. Dremova, Polym. Sci. Ser. B, 59:3 (2017), 257–267
S. D. Varfolomeev, E. N. Efremenko, I. V. Lyagin, Russ. Chem. Rev., 86:4 (2017), 339–355
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