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Development of Entero Sorbent Technology for Agriculture Based on Mechanically Activated Hydrolytic Lignin


Affiliations
1 Dsc, Professor, Department of Polymer Chemistry and Chemical Technology, Samarkand State University, University Blv. 15, Samarkand, Uzbekistan
2 Doctoral Student Ph.D., Department of Physical and Colloid Chemistry, Samarkand State University, University Blv. 15, Samarkand, Uzbekistan
 

In this article, one of the possible options for the use of a complex nano sorbent based on hydrolytic lignin is considered - the prevention of mycotoxicoses in farm animals and is described in its production technology.

Agricultural feeds are produced and exported in Uzbekistan and most of the raw materials for their production are contaminated with mycotoxins. Mycotoxins are waste products of microscopic molds. They enter the gastrointestinal tract of farm animals with contaminated feed and cause poisoning - mycotoxicosis.

According to the test results (mycotoxins at a concentration of 200 μg/kg were added to the feed and adsorbents at the level of 0.5% of the feed), the maximum absorption rate of zearalenone was 58%, ochratoxin A - 54%, deoxynivalenol - no more than 40%, T-2 toxin - not more than 30%. Currently, there is no single drug that has universal adsorption and inactivating activity against all major mycotoxins.


Keywords

Deoxynivalenol (DON), T-2 toxin, zearalenone, ochratoxin A, mycotoxin, optimization
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  • Agriopoulou S, Stamatelopoulou E, Varzakas T. Advances in occurrence, importance, and mycotoxin control strategies: Prevention and detoxification in foods. Foods. 2020;9(2):137.
  • Raduly Z, Szabó L, Madar A, et al. Toxicological and medical aspects of Aspergillus-derived mycotoxins entering the feed and food chain. Frontiers in microbiology. 2020;10:2908.
  • Lyagin I, Efremenko E. Enzymes for detoxification of various mycotoxins: Origins and mechanisms of catalytic action. Molecules. 2019;24(13):2362.
  • Su QY. The Toxification and Detoxification Mechanisms of Aflatoxin B1 in Human: An Update. InAflatoxin B1 Occurrence, Detection and Toxicological Effects. IntechOpen.
  • Bobomurodova, S.Y., Fayzullaev, N.I., et al. Catalytic aromatization of oil satellite gases//International Journal of Advanced Science and Technology, 2020, 29(5):3031–3039.
  • Fayzullaev, N.I., Bobomurodova, S.Y, et al. Catalytic change of C1-C4-alkanes//International Journal of Control and Automation, 2020;13(2):827–835.
  • Mamadoliev, I.I., Fayzullaev, et al. Synthesis of high silicon of zeolites and their sorption properties//International Journal of Control and Automation, 2020;13(2):703–709.
  • Mamadoliev, I.I., Fayzullaevet al.Optimization of the activation conditions of high silicon zeolite//International Journal of Advanced Science and Technology, 2020;29(3): 6807–6813.
  • Omanov BS, Xatamova MS, Fayzullaev NI, et al. Optimization of vinyl acetate synthesis process. International Journal of Control and Automation. 2020;13(1):231-8.
  • Ibodullayevich FN, Yunusovna BS, Anvarovna XD. Physico-chemical and texture characteristics of Zn-Zr/VKTS catalyst. Journal of Critical Reviews. 2020;7(7):917-20.
  • Sartova K, Omurzak E, Kambarova G, et al. Activated carbon obtained from the cotton processing wastes. Diamond and Related Materials. 2019;91:90-7.
  • Tkachenko T, Sheludko Y, Yevdokymenko V, et al. Physico-chemical properties of flax microcrystalline cellulose. Applied Nanoscience. 2022;12(4):1007-20.
  • Bogaev AV, Gorelova OM, et al. The study of the regularities of the process of pyrolysis of the pine nut shell and the production of activated carbon with desired properties on its basis. Water treatment. 2016(4):17-21.
  • Zhang J, Tahmasebi A, Omoriyekomwan JE et al. Direct synthesis of hollow carbon nanofibers on bio-char during microwave pyrolysis of pine nut shell. Journal of Analytical and Applied Pyrolysis. 2018;130:142.
  • Afolabi OO, Sohail M, Thomas CL. Characterization of solid fuel chars recovered from microwave hydrothermal carbonization of human biowaste. Energy. 2017 Sep 1;134:74-89.
  • Tabakaev R, Kanipa I, Astafev A et al. Thermal enrichment of different types of biomass by low-temperature pyrolysis. Fuel. 2019;245:29-38.
  • Kambarova GB, Sarymsakov S. Preparation of activated charcoal from walnut shells. Solid Fuel Chemistry. 2008;42(3):183-6.
  • Wang W, Qi J, Sui Y, et al. An asymmetric supercapacitor based on activated porous carbon derived from walnut shells and NiCo2O4 nanoneedle arrays electrodes. Journal of nanoscience and nanotechnology. 2018;18(8):5600-8.
  • Farberova EA, Tingaeva EA, Chuchalina AD et al. Obtaining granulated active carbon from wastes of vegetable raw materials. Izvestiya Vysshikh Uchebnykh Zavedenii Khimiya I Khimicheskaya Tekhnologiya. 2018; 61(3):51-7.
  • Zabihi M, Asl AH, Ahmadpour AH. Studies on adsorption of mercury from aqueous solution on activated carbons prepared from walnut shell. Journal of hazardous materials. 2010;174(1-3):251-6.
  • Xolmirzayeva HN, Fayzullayev NI. Obtaining Nanocarbon from Local Raw Materials and Studying Its Textural and Sorption Properties. arXiv preprint arXiv:2202.11751. 2022.
  • Fayzullaev NI, Kholmirzaeva HN, Normo’minov AU. Synthesis And Study Of High-Silicon Zeolites From Natural Bentonite. Solid State Technology. 2020;63(6):3448-59.
  • Lewicka K. Activated carbons prepared from hazelnut shells, walnut shells and peanut shells for high CO2 adsorption. Polish Journal of Chemical Technology. 2017;19(2).
  • Suhdi S, Wang SC. The Production of Carbon Nanofiber on Rubber Fruit Shell-Derived Activated Carbon by Chemical Activation and Hydrothermal Process with Low Temperature. Nanomaterials. 2021;11(8):2038.
  • Tursunova NS, Fayzullaev NI. Kinetics of the reaction of oxidative dimerization of methane. International Journal of Control and Automation. 2020;13(2):440-6.
  • Fayzullaev NI, Sh SB. Catalytic aromatization of methane with non-mo-contained catalysts. Austrian journal of technical and natural sciences. 2018(7-8):73-80.
  • Fayzullayev NI. Kinetics and mechanism of the reaction of the catalytic oxycondensation reaction of methane. Austrian Journal of Technical and Natural Sciences. 2019(5-6):62-8.

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  • Development of Entero Sorbent Technology for Agriculture Based on Mechanically Activated Hydrolytic Lignin

Abstract Views: 165  |  PDF Views: 1

Authors

Normurot I. Fayzullayev
Dsc, Professor, Department of Polymer Chemistry and Chemical Technology, Samarkand State University, University Blv. 15, Samarkand, Uzbekistan
Khilola N. Kholmirzayeva
Doctoral Student Ph.D., Department of Physical and Colloid Chemistry, Samarkand State University, University Blv. 15, Samarkand, Uzbekistan

Abstract


In this article, one of the possible options for the use of a complex nano sorbent based on hydrolytic lignin is considered - the prevention of mycotoxicoses in farm animals and is described in its production technology.

Agricultural feeds are produced and exported in Uzbekistan and most of the raw materials for their production are contaminated with mycotoxins. Mycotoxins are waste products of microscopic molds. They enter the gastrointestinal tract of farm animals with contaminated feed and cause poisoning - mycotoxicosis.

According to the test results (mycotoxins at a concentration of 200 μg/kg were added to the feed and adsorbents at the level of 0.5% of the feed), the maximum absorption rate of zearalenone was 58%, ochratoxin A - 54%, deoxynivalenol - no more than 40%, T-2 toxin - not more than 30%. Currently, there is no single drug that has universal adsorption and inactivating activity against all major mycotoxins.


Keywords


Deoxynivalenol (DON), T-2 toxin, zearalenone, ochratoxin A, mycotoxin, optimization

References