22594nam#a2201561#i#4500001000500000005001700005008004000022020002300062041000900085044000900094072029100103080049100394084004600885084005100931084005200982084008401034084003201118084005301150084005901203084006301262084004601325084005101371084005801422084005201480084008201532084003201614084005201646084015101698084011201849084005501961084017702016084005702193084003802250084003602288084004402324100009702368100006202465100010302527100010102630100010802731100017302839100011203012100010503124100016603229100009903395100011503494100018203609100010803791100007003899100013503969100006904104100018204173100018404355100010504539100014204644100010804786100006904894100006604963100005905029100010905088100006805197100017805265100010305443100017205546100010605718100010605824100011005930100010606040100014106146100006606287100007106353100017906424100006606603100011206669100017906781100014106960100013907101245004707240260004407287300001207331500155907343510030608902510030409208510023509512510025309747510021510000510022210215510028510437510027410722510022010996510021311216510019211429510040911621510028912030510024012319510023312559510034812792510026213140510025713402510037413659510018214033510025014215510014214465510014614607510021514753510018314968510024215151510026415393510030815657510020815965510026416173510028016437510021616717510018816933510021117121510013017332510026317462510025817725510022817983510020318211510025418414510029118668510025318959510024119212510021119453510020319664510022619867510026920093510037220362510024920734533003320983856001621016182520240426042723.5  20200211d2020####ek#y0engy0150####ca##$a978-5-369-02026-50#$aRUS##$axxu#7$aBiotechnology. SCI010000$aChemistry / Organic. SCI013040$aChemistry / Toxicology. SCI013090$aEnvironmental Science (see also Chemistry / Environmental). SCI026000$aLife Sciences / Biochemistry. SCI007000$aLife Sciences / Biophysics. SCI009000$aLife Sciences / Ecology. SCI020000##$aМатематика. 51$aХимия. Кристаллография. Минералогия. Минераловедение. 54$aБиологические науки. 57$aМедицина. Охрана здоровья. 61$aСельское хозяйство. Лесное хозяйство. Охота. Рыбное хозяйство. 63$aХимическая технология. Химическая промышленность. Родственные отрасли. 66##$aХимические науки. 242bbk##$aОрганическая химия. 2422bbk##$aБиологические науки. 282bbk##$aФармакология. Фармация. Токсикология. 5282bbk##$aХимия. 04.03.012okso##$aХимические науки. 04.07.012okso##$aБиологические науки. 06.07.012okso##$aХимическая технология. 18.03.012okso##$aХимические науки. 622tbk##$aОрганическая химия. 6222tbk##$aБиоорганическая химия. 62242tbk##$aПриродные полимеры. 62422tbk##$aФизическая химия. Химическая физика. 6262tbk##$aЭкология. 6362tbk##$aБиологические науки. 642tbk##$aМолекулярная биология. Общая морфология, биофизика, биохимия, физиология. 64122tbk##$aБиофизика, биохимия, физиология и экология растений. 64442tbk##$aОрганическая химия. 31.212grnti##$aБиоорганическая химия. Природные органические соединения и их синтетические аналоги. 31.232grnti##$aБиологическая химия. 31.272grnti##$aБиофизика. 34.172grnti##$aЭкология. 34.352grnti##$aТоксикология. 34.472grnti#1$aAndriyanova, Mariya Sergeevna$aScientific-Manufacturing Complex “Technological Center”#1$aAslanli, Aslanli Gul$aLomonosov Moscow State University#1$aBasova, Nataliya Evgen'evna$aSechenov Institute of Evolutionary Physiology and Biochemistry, RAS#1$aBykov, Viktor Ivanovich$aEmanuel Institute of Biochemical Physics, Russian Academy of Sciences#1$aVarfolomeev, Sergey Dmitrievich$aEmanuel Institute of Biochemical Physics Russian Academy of Sciences#1$aGorbunov, Konstantin Sergeevich$aFederal State Budgetary Institution Federal Research  Clinical Center for Physico-Chemical Medicine  of the Federal Biomedical Agency#1$aGorelenkov, Valentin Konstantinovich$aScientific Research Institute of Elastomeric Materials and Products#1$aGrigorenko, Bella Ludvigovna$aEmanuel Institute of Biochemical Physics Russian Academy of Sciences#1$aGudkov, Denis Andreevich$aFederal State Budgetary Institution Federal Research  Clinical Center for Physico-Chemical Medicine  of the Federal Biomedical Agency#1$aZavialov, Vasiliy Vladimirivich$aForensic Center of the Russian Ministry of Internal Affairs#1$aZavialova, Nataliya Vasil'evna$aBudgetary Establishment “27 Scientific Centre”of the Ministry of Defense#1$aZlobin, Alexander Vladimirovich$aFederal State Budgetary Establishment  «33 Central Scientific Research Test Institute» of the Ministry of Defense  of the Russian Federation#1$aEremenko, Arkadiy Veniaminovich$aEmanuel Institute of Biochemical Physics Russian Academy of Sciences#1$aEremin, Sergey Alexandrovich$aLomonosov Moscow State University#1$aErmakova, Inna Tihonovna$aG.K. Skryabin Institute of Biochemistry and Physiology of Microorganisms,  Russian Academy of Sciences#1$aEfremenko, Elena Nikolaevna$aLomonosov Moscow State University#1$aInozemcev, Valeriy Alexandrovich$aFederal State Budgetary Establishment «33 Central Scientific Research Test Institute» of the Ministry of Defense  of the Russian Federation#1$aKomissarenko, Sergey Anatol'evich$aFederal State Budgetary Establishment  «33 Central Scientific Research Test Institute» of the Ministry of Defense  of the Russian Federation#1$aKurochkin, Il'ya Nikolaevich$aEmanuel Institute of Biochemical Physics Russian Academy of Sciences#1$aLeontievsky, Alexey Arkad'evich$aG.K. Skryabin Institute of Biochemistry and Physiology of Microorganisms,  Russian Academy of Sciences#1$aLushchekina, Sofya Vladimirovna$aEmanuel Institute of Biochemical Physics Russian Academy of Sciences#1$aLyagin, Il'ya Vladimirovich$aLomonosov Moscow State University#1$aMaslova, Olga Vasil'evna$aLomonosov Moscow State University#1$aMasson, Patrick Ivon Moris$aKazan Federal University#1$aMahaeva, Galina Fayvelevna$aInstitute of Physiologically Active Substances Russian Academy of Sciences#1$aMahlis, Tat'yana Abramovna$aLomonosov Moscow State University#1$aMedveckiy, Igor Viktorovich$aFederal State Budgetary Establishment  «33 Central Scientific Research Test Institute» of the Ministry of Defense  of the Russian Federation#1$aMoralev, Sergey Nikolaevich$aSechenov Institute of Evolutionary Physiology and Biochemistry, RAS#1$aNelga, Igor Alikovich$aFederal State Budgetary Establishment  «33 Central Scientific Research Test Institute» of the Ministry of Defense  of the Russian Federation#1$aNechaeva, Nataliya Leonidovna$aEmanuel Institute of Biochemical Physics Russian Academy of Sciences#1$aNovichkova, Dana Alexandrovna$aEmanuel Institute of Biochemical Physics Russian Academy of Sciences#1$aNemuchin, Alexander Vladimirivich$aEmanuel Institute of Biochemical Physics Russian Academy of Sciences#1$aRozengart, Evgeniy Viktorovich$aSechenov Institute of Evolutionary Physiology and Biochemistry, RAS#1$aSviridov, Alexey Vladimirivich$aG.K. Skryabin Institute of Biochemistry and Physiology of Microorganisms,  Russian Academy of Sciences#1$aSen'ko, Ol'ga Vital'evna$aLomonosov Moscow State University#1$aStepanov, Nikolay Alekseevich$aLomonosov Moscow State University#1$aTretyakov, Sergey Vadimovich$aFederal State Budgetary Establishment  «33 Central Scientific Research Test Institute» of the Ministry of Defense  of the Russian Federation#1$aFrolov, George Alexandrovich$aInstitute of Steel and Alloys#1$aTsybenova, Svetlana Batozhargalovna$aEmanuel Institute of Biochemical Physics Russian Academy of Sciences#1$aSherstyuk, Artem Valer'evich$aFederal State Budgetary Establishment  «33 Central Scientific Research Test Institute» of the Ministry of Defense  of the Russian Federation#1$aShushkova, Tatyana Valentinovna$aG.K. Skryabin Institute of Biochemistry and Physiology of Microorganisms, Russian Academy of Sciences#1$aEpiktetov, Dmitriy Olegovich$aG.K. Skryabin Institute of Biochemistry and Physiology of Microorganisms,  Russian Academy of Sciences00$aORGANOPHOSPHORUS NEUROTOXINS$cMonography1#$aMoscow$bPublishing Center RIOR$c2020##$a380 p.##$aThe collective monograph is devoted to discussing the history of creation, studying the properties, neutralizing and using organophosphorus neurotoxins, which include chemical warfare agents, agricultural crop protection chemical agents (herbicides and insecticides) and medicines. The monograph summarizes the results of current scientific research and new prospects for the development of this field of knowledge in the 21st century, including the use of modern physicochemical methods for experimental study and theoretical analysis of biocatalysis and its mechanisms based on molecular modeling with supercomputer power. 
The book is intended for specialists who are interested in the current state of research in the field of organophosphorus neurotoxins. The monograph will be useful for students, graduate students, researchers specializing in the field of physical chemistry, physicochemical biology, chemical enzymology, toxicology, biochemistry, molecular biology and genetics, biotechnology, nanotechnology and biomedicine.$aorganophosphorus compounds, kinetic model, dynamics of the process, the human brain, inhibition of acetylcholinesterase, acetylcholine, neuromuscular contraction, cholinergic synapse, synaptic cleft, degradation, immobilized enzymes, environmental safety, hydrolases, oxidoreductases, C-P-bound, cholinesterase, phosphatase, organophosphate hydrolase, catalysis mechanism, active center, metal ions, computer modeling, self-detoxification, composite protective materials, microbial biodegradation$a10.29039/02026-50#$aAslanli A.G., Stepanov N.A., Senko O.V., Maslova O.V., Lyagin I.V., Efremenko E.N. The hexahistidine containing organophosphorus hydrolase enzyme and bacterial cellulose based functional materials. In IOP Conference Series: Materials Science and Engineering, 2019, 525 (1). P. 012005. IOP Publishing.0#$aAslanly A.G., Maslova O.V., Sen'ko O.V., Efremenko E.N. Polifunkcional'nyy fermentnyy biopreparat na osnove geksagistidinsoderzhaschey organofosfatgidrolazy, deystvuyuschiy protiv bakterioza rasteniy. Vestnik biotehnologii i fiziko-himicheskoy biologii imeni Yu.A. Ovchinnikova, 2017, 13. S. 13-17.0#$aAslanli A., Lyagin I., Efremenko E. Charges' interaction in polyelectrolyte (nano)complexing of His6-OPH with peptides: unpredictable results due to imperfect or useless concept? Int. J. Biol. Macromol., 2019, 140. Pp. 368–376.0#$aBoroduleva A.Y., Wu J., Yang Q., Li H., Zhang Q., Li P., Eremin. S.A. Development of fluorescence polarization immunoassays for parallel detection of pesticides carbaryl and triazophos in wheat grains. Anal. Methods, 2017, 9 (48). Pp. 6814–6822.0#$aBravaya K.B., Bochenkova A.V., Grigorenko B.L., Topol I.A., Burt S.K., Nemukhin A.V.  Molecular modeling the reaction mechanism of serine-carboxyl peptidases. J. Chem. Theory Comput., 2006, 2. Pp. 1168–1175.0#$aCarletti E.N., Colletier J.-P., Dupeux F., Trovaslet M., Masson P., Nachon F. Structural evidence that human acetylcholinesterase inhibited by tabun ages through O-dealkylation. J Med Chem, 2010, 53. Pp. 4002–4008.0#$aGrigorenko B.L., Novichkova D.A., Lushchekina S.V., Zueva I.V., Schopfer L.M., Nemukhin A.V., Varfolomeev S.D., Lockridge O., Masson P. Computer-designed active human butyrylcholinesterase double mutant with a new catalytic triad, Chem.-Biol. Interact., 2019, 306. Pp. 138–146.0#$aGudkov D.A., Lyagin I.V., Efremenko E.N., Kabanov A.V. Effect of dimerization on the catalytic properties of native and chimeric organophosphorus hydrolase determined by molecular modeling of the enzyme structure. Russian Chemical Bulletin, 2012, 1 (2), Pp. 449–455.0#$aGudkov D.A., Lyagin I.V., Verkhusha V.V., Efremenko E.N. Hybrid proteins with organophosphorus hydrolase activity and fluorescence of deGFP4 protein. Moscow University Chemistry Bulletin, 2011, 66 (2). Pp. 92–98.0#$aEfremenko E., Lyagin I., Gudkov D., Varfolomeyev S. Immobilized biocatalysts for detoxification of neurotoxic organophosphorous compounds. Biocatalysis and Biotransformation, 2007, 25 (2–4). Pp. 359–364.0#$aEfremenko E.N., Sen'ko O.V., Kuc V.V., Alenina K.A., Holstov A.V., Ismailov A.D. Lyuminescentnyy biokatalizator dlya opredeleniya toksikantov. Patent RF na izobretenie № 2394910, 2010.0#$aEfremenko E.N., Zav'yalova N.V., Lyagin I.V., Sen'ko O.V., Gudkov D.A., Aksenov A. V., Stepanov N.A., Sirotkina M.S., Spiricheva O.V., Ivanov R.V., Lozinskiy V.I., Varfolomeev S.D., Kondrat'ev V.B., Holstov V.I. Sposob biorazlozheniya fosfororganicheskih soedineniy v sostave reakcionnyh mass, poluchaemyh posle himicheskogo unichtozheniya veschestva tipa VX. Patent RF na izobretenie № 2408724, 2009.0#$aEremenko A.V., Prokopkina T.A., Kasatkin V.E., Osipova T.A., Kurochkin I.N. Planarnye tiol-chuvstvitel'nye sensornye elementy dlya opredeleniya aktivnosti butirilholine¬sterazy i analiza ee ingibitorov. Vestnik Moskovskogo Universiteta. Seriya 2. Himiya, 2014, 55 (3). S. 174–179.0#$aEfremenko E.N., Lyagin I.V., Klyachko N.L., Bronich T., Zavyalova N.V., Jiang Y., Kabanov A.V. A simple and highly effective catalytic nanozyme scavenger for organophosphorus neurotoxins. J. Control. Release, 2017, 247. Pp. 175–181.0#$aEfremenko E.N., Lyagin I.V., Zav'yalov V.V., Zav'yalova N.V., Holstov V.I., Yankovskaya A.A. Razryv S-R svyazi v fosfonatah pod deystviem fermentnyh biokatalizatorov. Teoreticheskaya i prikladnaya ekologiya, 2015, 3. C. 47–540#$aEfremenko E.N., Lyagin I.V., Gudkov D.A., Stepanov N.A., Sen'ko O.V., Maslova O.V., Kovalev D.A., Zav'yalova N.V.,  Holstov V.I., Yankovskaya A.A. Kombinirovannoe primenenie fermentnogo i bakterial'nogo biokatalizatorov v processah biodestrukcii FOV i produktov ih razlozheniya. Teoreticheskaya i prikladnaya ekologiya, 2015, (3). S. 35–39.0#$aEremenko A.V., Dontsova E.A., Nazarov A.P., Evtushenko E.G., Amitonov S.V., Savilov S.V., Martynova L.F., Lunin V.V., Kurochkin I.N. Manganese Dioxide Nanostructures as a Nov¬el Electrochemical Mediator for Thiol Sensors. Electroanalysis, 2012, 3. P. 573.0#$aErmakova I.T., Shushkova T.V., Sviridov A.V., Zelenkova N.F., Vinokurova N.G., Baskunov B.P., Leontievsky A.A. Organophosphonates utilization by soil strains of Ochrobactrum anthropi and Achromobacter sp. Arch. Microbiol., 2017, 199(5). Pp. 665–675.0#$aFilimonov I.V., Yankovskaya A.A., Kuzhelko S.V., Zav'yalov V.V., Zav'yalova N.V., Golipad A.N., Kolesnikov D.P., Kovtun V.A., Holstov V.I., Lyagin I.V., Efremenko E.N. Issledovaniya v sfere perspektivnogo ispol'zovaniya himiko-biologicheskih i medicinskih biokataliticheskih tehnologiy v interesah Vooruzhennyh Sil. Vestnik voysk RHB zaschity, 2018, 2 (2). S. 18–50.0#$aHua X., Eremin S.A., Liu F., Wang M. Antibody Developments and Immunoassays for Organophosphorus Chemicals: A Review. Current Organic Chemistry, 2017, 21 (26). Pp. 2640–2652.0#$aLiu Y., Liu R., Boroduleva A., Eremin S., Guo Y., Zhu G. A highly specific and sensitive fluorescence polarization immunoassay for the rapid detection of triazophos residue in agricultural products. Anal. Methods, 2016, 8 (36). Pp. 6636–6644.0#$aLyagin I.V., Efremenko E.N., Varfolomeev S.D. Fermentnye biosensory dlya opredeleniya pesticidov. Uspehi himii, 2017, 86. Pp. 339–355.0#$aLyagin I., Efremenko E. Theoretical evaluation of suspected enzymatic hydrolysis of Novichok agents. Catal. Commun., 2019, 120. Pp. 91–94.0#$aLyagin I.V., Andrianova M.S., Efremenko E.N. Extensive hydrolysis of phosphonates as unexpected behaviour of the known His6-organophosphorus hydrolase. Appl. Microbiol. Biotechnol., 2016, 100. Pp. 5829–5838.0#$aLyagin I., Efremenko E. Enzymes for Detoxification of Various Mycotoxins: Origins and Mechanisms of Catalytic Action. Molecules, 2019, 24. e2362, doi: 10.3390/molecules24132362.0#$aLushchekina S.V., Schopfer L.M., Grigorenko B.L., Nemukhin A.V., Varfolomeev S.D., Lockridge O., Masson P. Optimization of Cholinesterase-Based Catalytic Bioscavengers Against Organophosphorus Agents, Front. Pharmacol., 2018, 9. P. 211.0#$aMakhaeva G.F., Rudakova E.V., Serebryakova O.G., Aksinenko A.Y., Lushchekina S.V., Bachurin S.O., Richardson R.J. Esterase profiles of organophosphorus compounds in vitro predict their behavior in vivo, Chem.-Biol. Interact., 2016, 259 (Pt B). Pp. 332–342.0#$aMaslova O.V., Stepanov N.A., Grigoryeva A.I., Bruyako M.G., Efremenko E.N. New effective His6-OPH-containing mineral carriers pretreated by low-temperature plasma for destruction of organophosphates in different types of soil. International Journal of Pharmacy & Technology, 2016, 8. Pp. 27317–27333.0#$aMaslova O., Aslanli A., Stepanov N., Lyagin I., Efremenko E. Catalytic characteristics of new antibacterials based on hexahistidine-containing organophosphorus hydrolase. Catalysts, 2017, 7 (9). P. 271.0#$aMaslova O.V., Senko O.V., Stepanov N.A., Aslanli A.G.Q., Efremenko E.N. His6-OPH and its stabilized forms combating quorum sensing molecules of gram-negative bacteria in combination with antibiotics. Jundishapur J. Nat. Pharm. Prod., 2017, 12 (3). P. e63649.0#$aMaslova O.V., Aslanly A.G., Sen'ko O.V., Efremenko E.N. Vozmozhnosti snizheniya minimal'nyh ingibiruyuschih koncentraciy puromicina i ceftiofura pri ih sochetanii s biopreparatami na osnove His6-OPH. Vestnik Moskovskogo universiteta. Seriya 2 Himiya, 2018, 59. S. 439–444.0#$aMasson P., Nachon F., Broomfield C.A. et al. A collaborative endeavor to design cholinesterase-based catalytic scavengers against toxic organophosphorus esters. Chem. Biol. Interact., 175 (2008). Pp. 273–280.0#$aMasson P., Nachon F. Cholinesterase reactivators and bioscavengers for pre- and post-exposure treatments of organophosphorus poisoning, J. Neurochem., 2017, 142 Suppl 2. Pp. 26–40.0#$aMehta J., Dhaka S., Paul A.K., Dayananda S., Deep A. Organophosphate hydrolase conjugated UiO-66-NH2 MOF based highly sensitive optical detection of methyl parathion. Environ. Res., 2019, 174. Pp. 46–53.0#$aMoralev S.N., Rozengart E.V. Comparative Enzymology of Cholinesterases, IUL Biotechnology Series La Jolla, CA (2007). 484 p.0#$aNechaeva N., Prokopkina T., Makhaeva G., Rudakova E., Boltneva N., Dishovsky C., Ere¬menko A., Kurochkin I. Quantitative butyryl¬cholinesterase activity detection by surface-en-hanced Raman spectroscopy. Sensors and Actu¬ators B., 2018, 259. Pp. 75–82.0#$aNel'ga I.A., Medveckiy I.V., Zlobin A.V., Tre¬t'yakov S.V., Sherstyuk A.V., Kostyuchenko I.V. Himicheskoe oruzhie: istoriya issledovaniya fosfororganicheskih otravlyayuschih veschestv za rubezhom. Vestnik voysk RHB zaschity, 2019, 3 (2). S. 175–193.0#$aNemukhin A.V., Lushchekina S.V., Bochenkova A.V., Golubeva A.A., Varfolomeev S.D. Characterization of a complete cycle of acetylcholinesterase catalysis by ab initio QM/MM modeling. J. Mol. Model., 2008, 14. Pp. 409–416.0#$aSupotnickiy M.V., Shilo N.I., Kovtun V.A. Himicheskoe oruzhie v irano-irakskoy voyne 1980–1988 godov. 1. Podgotovka Iraka k himicheskoy voyne. Vestnik voysk RHB zaschity, 2019, 1 (3). S. 40–64.0#$aShushkova T.V., Vinokurova N.G., Baskunov B.P., Zelenkova N.F., Sviridov A.V., Ermakova I.T., Leontievsky A.A. Glyphosate acetylation as a specific trait of Achromobacter sp. Kg 16 physiology. Appl. Microbiol. Biotechnol., 2016, 100. Pp. 847–855.0#$aSenko O., Gladchenko M., Maslova O., Efremenko E. Long-term storage and use of artificially immobilized anaerobic sludge as a powerful biocatalyst for conversion of various wastes including those containing xenobiotics to biogas. Catalysts, 2019, 9. P. e326, DOI: 10.3390/catal9040326.0#$aSenko O., Stepanov N., Tyutyunov A., Sterlin S., Grinberg V., Makhlis T., Efremenko E. Intensification of organophosphorus hydrolase synthesis by using substances with gas-transport function. Appl. Sci., 2017, 7. P. e1305, DOI: 10.3390/app7121305.0#$aSenko O., Maslova O., Efremenko E. Optimization of the use of His6-OPH-based enzymatic biocatalysts for the destruction of chlorpyrifos in soil. International journal of environmental research and public health, 2017, 14 (12). P. 1438.0#$aSviridov A.V., Shushkova T.V., Ermakova I.T., Ivanova E.V., Epiktetov D.O., Leontievsky A.A. Microbial degradation of glyphosate herbicides (Review). Appl. Biochem. Microbiol., 2015, 51 (2). Pp. 188–195.0#$aVarfolomeev S.D., Semenova N.A., Bykov V.I., Cybenova S.B. Kinetika himicheskih processov v mozge cheloveka. Modelirovanie BOLD-signala pri fMRT issledovanii. Doklady AN, 2019, 488 (2). S. 39–43.0#$aVarfolomeev S.D., Semenova N.A., Ublinskiy M.V., Bykov V.I., Tsybenova S.B. fMRI and MR-spectroscopy in research on triggering and autostabilization of N-acetylaspartate. Chemical Physics Letters, 2019, 729. Pp. 84–91.0#$aWang P., Li H., Hassan M.M., Guo Z., Zhang Z.Z., Chen Q. Fabricating an Acetylcholinesterase Modulated UCNPs-Cu2+ Fluorescence Biosensor for Ultrasensitive Detection of Organophosphorus Pesticides-Diazinon in Food. J. Agric. Food Chem., 2019, 67. Pp. 4071–4079.0#$aZav'yalov V.V., Kuzhelko S.V., Zav'yalova N.V., Kovtun V.A., Holstov V.I., Taranchenko Yu.F., Slastilova L.M.,   Efremenko E.N., Sen'kilev A.P. Sovremennye napravleniya sozdaniya novyh zaschitnyh materialov i tkaney dlya sredstv individual'noy i kollektivnoy zaschity ot toksichnyh himikatov i kletok patogenov. Vestnik voysk RHB zaschity, 2019, 3 (3). S. 117–148.0#$aZhang H., Yang S., Ruyck K.D., Beloglazova N., Eremin S.A., Saeger S.D., Zhang S., Shen J., Wang Z. Fluorescence polarization assays for chemical contaminants in food and environmental analyses. Trends in Anal. Chem., 2019, 114. Pp. 293–313.##$aThere is an electronic copy4#$anaukaru.ru