Effectiveness of Magnetic Bentonite Nanocomposites as Mycotoxin Binders in Dairy Baluchi Ewe's Diets: Impact on Milk Yield, Composition, Blood Chemistry, and Aflatoxin M1 Levels
محورهای موضوعی : Small Ruminant ReproductionE. Ibrahimi Khoram Abadi 1 , S. Heydari 2
1 - Department of Animal Science, Faculty of Agriculture and Animal Science, University of Torbat-e Jam, Torbat-e Jam, Iran
2 - Department of Chemistry, University of Torbat-e Jam, Torbat-e Jam, Iran
کلید واژه: bentonite, milk, mycotoxin, nanocomposites, plasma metabolites, toxin binders,
چکیده مقاله :
Bentonite is considered the most effective adsorbent for aflatoxin (AF) decontamination, and recent studies have shown that changing its structure in nano form improves its physicochemical properties and chemical stability. This study was aimed to evaluate the effectiveness of different types of bentonites as binders on performance, plasma metabolites, and aflatoxin M1 (AFM1) levels in contaminated milk of Baluchi ewes. The study was conducted with 12 ewes randomly assigned to four different experimental diets. The experi-mental diets were: (1) control (the basal diet had no supplements and contained bakery waste naturally con-taminated with AF); (2) control diet supplemented with natural bentonite (NB) (5 g/kg DM); (3) control diet supplemented with modified bentonite (MB) (5 g/kg DM) and (4) control diet supplemented with magnetic bentonite nanocomposite (MBNC) (5 g/kg DM). The study found that adding bentonite clays to the diet of ewes resulted in increased milk yield (P0.05). The study also found that increasing aflatoxin B1 (AFB1) intake resulted in a decreased carryover of AFB1 into AFM1 (P<0.01), with MBNC having the lowest carryover compared to other treatments (P<0.01). These results suggest that modification of bentonite structure in nanocomposite form improves chemical stability, physicochemical properties, and efficiency as novel toxin binders for crops and animal products.
Bentonite is considered the most effective adsorbent for aflatoxin (AF) decontamination, and recent studies have shown that changing its structure in nano form improves its physicochemical properties and chemical stability. This study was aimed to evaluate the effectiveness of different types of bentonites as binders on performance, plasma metabolites, and aflatoxin M1 (AFM1) levels in contaminated milk of Baluchi ewes. The study was conducted with 12 ewes randomly assigned to four different experimental diets. The experi-mental diets were: (1) control (the basal diet had no supplements and contained bakery waste naturally con-taminated with AF); (2) control diet supplemented with natural bentonite (NB) (5 g/kg DM); (3) control diet supplemented with modified bentonite (MB) (5 g/kg DM) and (4) control diet supplemented with magnetic bentonite nanocomposite (MBNC) (5 g/kg DM). The study found that adding bentonite clays to the diet of ewes resulted in increased milk yield (P0.05). The study also found that increasing aflatoxin B1 (AFB1) intake resulted in a decreased carryover of AFB1 into AFM1 (P<0.01), with MBNC having the lowest carryover compared to other treatments (P<0.01). These results suggest that modification of bentonite structure in nanocomposite form improves chemical stability, physicochemical properties, and efficiency as novel toxin binders for crops and animal products.
Abdin M., Ahmad M.M. and Javed S. (2010). Advances in mo-lecular detection of Aspergillus: An update. Arch. Microbiol. 192, 409-425.
Agag B.I. (2003). Prevention and control of mycotoxins in feeds. Assiut Univ. Bulletin. Environ. Res. 6, 149-166.
Ankom Technology. (2006). Neutral Detergent Fiber in Feeds-filter Bag Technique. Available at: https://www.ankom.com/sites/default/files/documentfiles/Method_6_NDF_A200.pdf.
AOAC. (2005). Official Methods of Analysis. 18th Ed. Associa-tion of Official Analytical Chemists, Gaithersburg, MD, USA.
Apajalahti J., Vienola K., Raatikainen K., Holder V. and Moran C.A. (2019). Conversion of branched-chain amino acids to corresponding isoacids—An in vitro tool for estimating ru-minal protein degradability. Front. Vet. Sci. 6, 311-321.
Awuchi C.G., Ondari E.N., Ogbonna C.U., Upadhyay A.K., Baran K., Okpala C.O.R., Korzeniowska M. and Guiné R.P. (2021). Mycotoxins affecting animals, foods, humans, and plants: Types, occurrence, toxicities, action mechanisms, prevention, and detoxification strategies-A revisit. Foods. 10, 1279-1285.
Bama K. and Sundrarajan M. (2017). Ag/TiO2/bentonite nano-composite for biological applications: Synthesis, characteriza-tion, antibacterial and cytotoxic investigations. Adv. Powder. Technol. 28, 2265-2280.
Battacone G., Nudda A., Palomba M., Mazzette A. and Pulina G. (2009). The transfer of aflatoxin M1 in milk of ewes fed diet naturally contaminated by aflatoxins and effect of inclusion of dried yeast culture in the diet. J. Dairy Sci. 92, 4997-5004.
Benkerroum N. (2020). Aflatoxins: Producing-Molds, Structure, Health Issues and Incidence in Southeast Asian and Sub-Saharan African Countries. Int. J. Environ. Res. Public Health. 17, 1215-1227.
Boyd J.W. (1984). The interpretation of serum biochemistry test results in domestic animals. Vet. Clin. Pathol. 13, 7-14.
Chouikhi N., Cecilia J.A., Vilarrasa-García E., Besghaier S., Chlendi M., Duro F.I.F., Castellon E.R. and Bagane M. (2019). CO2 adsorption of materials synthesized from clay minerals: A review. Minerals. 9, 514-522.
Degtyareva I.A., Ezhkova A.M., Yapparov A.K., Yapparov I.A., Ezhkov V.O., Babynin E.V., Davletshina A.Y., Motina T.Y. and Yapparov D.A. (2016). Production of nano-bentonite and the study of its effect on mutagenesis in bacteria Salmonella typhimurium. Nanotechnol. Russia. 11, 663-670.
Diaz D.E., Hagler W.M., Blackwelder J.T., Eve J.A., Hopkins B.A., Andersen K.L., Jones F.T. and Whitlow L.W. (2004). Aflatoxin binders II: Reduction of aflatoxin M1 in milk by sequestering agents of cows consuming aflatoxin in feed. Mycopathologia. 157, 233-241.
El-Kady A.A., Sharaf H.A., Abou-Donia M.A., Abbès S., Ben Salah-Abbès J., Naguib K., Oueslati R. and Abdel-Wahha M.A. (2009). Adsorption of Cd2+ ions on an Egyptian mont-morillonite and toxicological effects in rats. Appl. Clay Sci. 44, 59-66.
El-Nile A., Elazab M., El-Zaiat H., El-Azrak K.E., Elkomy A., Sallam S. and Soltan Y. (2021). In vitro and in vivo assess-ment of dietary supplementation of both natural or nano-zeolite in goat diets: Effects on ruminal fermentation and nu-trient digestibility. Animals. 11, 2215-2224.
Gan F., Hang X., Huang Q. and Deng Y. (2019). Assessing and modifying China bentonites for aflatoxin adsorption. Appl. Clay Sci. 168, 348-354.
Gouda G.A., Khattab H.M., Abdel-Wahhab M.A., Abo El Nor S.A., El-Sayed H.M. and Kholif S.M. (2019). Clay minerals as sorbents for mycotoxins in lactating goats’ diets: Intake, di-gestibility, blood chemistry, ruminal fermentation, milk yield and composition, and milk AFM1 content. Small Rumin. Res. 175, 15-22.
Hamad G.M., El-Makarem H.A., Abd Elaziz A.I., Amer A.A., El-Nogoumy B.A. and Abou-Alella S.A. (2022). Adsorption effi-ciency of sodium and calcium bentonite for ochratoxin A in some Egyptian cheeses: An innovative fortification model, in vitro and in vivo experiments. World Mycotoxin J. 15, 285-300.
Hamad G.M., El-Makarem H.A., Allam M.G., El Okle O.S., El-Toukhy M.I., Mehany T., El-Halmouch Y., Abushaala M.M.F., Saad M.S., Korma S.A., Ibrahim S.A., Hafez E.E., Amer A. and Ali E. (2023a). Evaluation of the adsorption effi-cacy of bentonite on aflatoxin M1 levels in contaminated milk. Toxins. 15, 107-117.
Hamad G.M., Mehany T., Simal-Gandara J., Abou-Alella S., Esu O.J., Abdel-Wahhab M.A. and Hafez E.E. (2023b). A review of recent innovative strategies for controlling mycotoxins in foods. Food Control. 144, 1-12.
Heydari S., Zare L. and Ghiasi H. (2019). Plackett–Burman ex-perimental design for the removal of diazinon pesticide from aqueous system by magnetic bentonite nanocomposites. J. Appl. Res. Water Wastewater. 11, 45-50.
Hosten A.O. (1990). BUN and creatinine. Pp. 874-878 in Clinical Methods: The History, Physical, and Laboratory Examina-tions. H.K. Walker, W.D. Hall and J.W. Hurst, Eds., Butter-worths, Boston, Massachusetts.
Huang Z., Li Y., Chen W., Shi J., Zhang N., Wang X., Li Z., Gao L. and Zhang Y. (2017). Modified bentonite adsorption of or-ganic pollutants of dye wastewater. Mater. Chem. Phys. 202, 266-276.
Iranian Council of Animal Care. (1995). Guide to the Care and Use of Experimental Animals, vol. 1. Isfahan University of Technology, Isfahan, Iran.
Ivan M., Dayrell M.S., Mahadevan S. and Hidiroglou M. (1992). Effects of bentonite on wool growth and nitrogen metabolism in fauna-free and faunated sheep. J. Anim. Sci. 70, 3194-202.
Jouany J.P. (2007). Methods for preventing, decontaminating and minimizing the toxicity of mycotoxins in feeds. Anim. Feed Sci. Technol. 137, 342-362.
Kazemi M., Eskandary Torbaghan A., Tahmasbi A.M., Valizadeh R. and Naserian A.A. (2017). Effects of phosalone consump-tion via feeding with or without sodium bentonite on perform-ance, blood metabolites and its transition to milk of Iranian Baluchi sheep. J. Anim. Sci. 59, 10-21.
Khadem A.A., Soofizadeh M. and Afzalzadeh A. (2007). Produc-tivity, blood metabolites and carcass characteristics of fatten-ing Zandi lambs fed sodium bentonite supplemented total mixed rations. Pakistan J. Biol. Sci. 10, 3613-3619.
Kholif A.E., Gouda G.A., Morsy T.A., Salem A.Z.M., Lopez S. and Kholif A.M. (2015). Moringa oleifera leaf meal as a pro-tein source in lactating goat’s diets: Feed intake, digestibility, ruminal fermentation, milk yield and composition, and its fatty acids profile. Small Rumin. Res. 129, 129-137.
Kholif A.E., Khattab H.M., El-Shewy A.A., Salem A.Z.M., Kholif A.M., El-Sayed M.M., Gado H.M. and Mariezcurrena M.D. (2014). Nutrient digestibility, ruminal fermentation activities, serum parameters and milk production and composition of lac-tating goats fed diets containing rice straw treated with Pleuro-tus ostreatus. Asian-Australasian J. Anim. Sci. 27, 357-364.
Kholif A.E., Morsy T.A., Gouda G.A., Anele U.Y. and Galyean M.L. (2016). Effect of feeding diets with processed Moringa oleifera meal as protein source in lactating Anglo-Nubian goats. Anim. Feed Sci. Technol. 217, 45-55.
Mahadevan H., Dev V.V., Krishnan K.A., Abraham A. and Er-shana O.C. (2018). Optimization of retention of phosphate species onto a novel bentonite-alum adsorbent system. Envi-ron. Technol. Innov. 9, 1-15.
Maki C.R., Monteiro A.P.A., Elmore S.E., Tao S., Bernard J.K., Harvey R.B., Romoser A.A. and Phillips T.D. (2016a). Calcium montmorillonite clay in dairy feed reduces aflatoxin concentrations in milk without interfering with milk quality, composition or yield. Anim. Feed Sci. Technol. 214, 130-135.
Maki C.R., Thomas A.D., Elmore S.E., Romoser A.A., Harvey R.B., Ramirez-Ramirez H.A. and Phillips T.D. (2016b). Effects of calcium montmorillonite clay and aflatoxin exposure on dry matter intake, milk production, and milk composition. J. Dairy Sci. 99, 1039-1046.
Martinez J.M., Volzone C. and Garrido L.B. (2017). Evaluation of polymeric Almodified bentonite for its potential application as ceramic coating. Appl. Clay Sci. 149, 20-27.
Maryan A.S. and Montazer M. (2015). Natural and organo-montmorillonite as antibacterial nanoclays for cotton garment. J. Ind. Eng. Chem. 22, 164-170.
Masoero F., Gallo A., Moschini M., Piv G. and Diaz D. (2007). Carryover of aflatoxin from feed to milk in dairy cows with low or high somatic cell counts. Animal. 1, 1344-1350.
Mavrogenis A.P. and Papachristoforou C. (1988). Estimation of the energy value of milk and prediction of fat-corrected milk yield in sheep and goats. Small Rumin. Res. 1, 229-236.
Morsy T.A., Kholif A.E., Kholif S.M., Kholif A.M., Sun X. and Salem A.Z.M. (2016). Effects of two enzyme feed additives on digestion and milk production in lactating Egyptian buffa-loes. Ann. Anim. Sci. 16, 209-222.
Morsy A.S., Soltan Y.A., El-Zaiat H.M., Alencar S.M. and Ab-dalla A.L. (2021). Bee propolis extract as a phytogenic feed additive to enhance diet digestibility, rumen microbial biosyn-thesis, mitigating methane formation and health status of late pregnant ewes. Anim. Feed Sci. Technol. 273, 114834-114841.
Moschini M., Gallo A., Piva G. and Masoero F. (2008). The ef-fects of rumen fluid on the in vitro aflatoxin binding capacity of different sequestering agents and in vivo release of the se-questered toxin. Anim. Feed Sci. Technol. 147, 292-309.
Murray H.H. (2006). Applied Clay Mineralogy, Occurrences, Processing and Application of Kaolins, Bentonites, Palygorskite-Sepiolite, and Common Clays, Bentonite Applications. Elsevier, the Netherland.
Nones J., Solhaug A., Eriksen G.S., Macuvele D.L.P., Poli A., Soares C., Trentin A.G., Riella H.G. and Nones J. (2017). Bentonite modified with zinc enhances aflatoxin B1 adsorp-tion and increase survival of fibroblasts (3T3) and epithelial colorectal adenocarcinoma cells (Caco-2). J. Hazard. Mater. 337, 80-89.
NRC. (2007). Nutrient Requirements: Sheep, Goats, Cervids, and New World Camelids. National Academy Press, Washington, DC, USA.
Ogunade I.M., Arriola K.G., Jiang Y., Driver J.P., Staples C.R. and Adesogan A.T. (2016). Effects of 3 sequestering agents on milk aflatoxin M 1 concentration and the performance and immune status of dairy cows fed diets artificially contaminated with aflatoxin B1. J. Dairy Sci. 99, 6263-6273.
Pandey S. (2017). A comprehensive review on recent developments in bentonite-based materials used as adsorbents for waste water treatment. J. Mol. Liquids. 241, 1091-1113.
Queiroz O.C.M., Han J.H., Staples C.R. and Adesogan A.T. (2012). Effect of adding a mycotoxin-sequestering agent on milk aflatoxin M1 concentration and the performance and immune response of dairy cattle fed an aflatoxin B1-contaminated diet. J. Dairy Sci. 95, 5901-5908.
Ramos S.C., Jeong C.D., Mamuad L.L., Kim S.H., Son A.R., Mi-guel M.A., Islam M., Cho Y.I. and Lee S.S. (2021). Enhanced ruminal fermentation parameters and altered rumen bacterial community composition by formulated rumen buffer agents fed to dairy cows with a high-concentrate diet. Agriculture. 11, 554-562.
SAS Institute. (2004). SAS®/STAT Software, Release 9.4. SAS Institute, Inc., Cary, NC. USA.
Soltan Y.A., Adibe Filho A.A., Abdalla A., Berenchtein B., Schiavinatto P. and Costa C. (2021a). Replacing maize with low tannin sorghum grains: Lamb growth performance, mi-crobial protein synthesis and enteric methane production. Anim. Prod. Sci. 61, 1348-1355.
Soltan Y.A., Morsy A.S., Hashem N.M. and Sallam S.M. (2021b). Boswellia sacra resin as a phytogenic feed supplement to en-hance ruminal fermentation, milk yield, and metabolic energy status of early lactating goats. Anim. Feed Sci. Technol. 277, 1-12.
Soltan Y.A., Morsy A.S., Hashem N.M., Elazab M., Sultan M., Marey H., Abo El Lail G., El-Desoky N., Hosny N., Mahdy A., Hafez E. and Sallam S. (2021c). Modified nano-montmorillonite and monensin modulate in vitro ruminal fer-mentation, nutrient degradability, and methanogenesis differ-ently. Animals. 11, 3005-3020.
Sulaymon A.H., Mohammed A.A. and Al-Musawi T.J. (2014). Comparative study of removal of cadmium (II) and chromium (III) ions from aqueous solution using low-cost biosorbent. Int. J. Chem. React. Eng. 12, 1-10.
Swain P.S., Rao S.B.N., Rajendran D., Dominic G. and Selvaraju S. (2016). Nano zinc, an alternative to conventional zinc as animal feed supplement: A review. Anim. Nutr. 2, 134-141.
Tate K., Yuan G., Theng B., Churchman G., Singh J. and Berben P. (2015). Can geophagy mitigate enteric methane emissions from cattle. J. Prelim. Res. 2, 1-8.
Upadhaya S.D., Park M.A. and Ha J.K. (2010). Mycotoxins and their biotransformation in the rumen: A review. Asian-Australasian J. Anim. Sci. 23, 1250-1260.
Van Soest P.J., Robertson J.B. and Lewis B.A. (1991). Methods for dietary fiber, neutral detergent fiber, and non-starch poly-saccharides in relation to animal nutrition. J. Dairy Sci. 74, 3583-3597.
Vila-Donat P., Marín S., Sanchis V. and Ramos A.J. (2018). A review of the mycotoxin adsorbing agents, with an emphasis on their multi-binding capacity, for animal feed decontamina-tion. Food Chem. Toxicol. 114, 246-259.
Walz L.S., White T.W., Fernandez J.M., Gentry L.R., Blouin D.C., Froetschel M.A., Brown T.F., Lupton C.J. and Chapa A.M. (1998). Effects of fish meal and sodium bentonite on daily gain, wool growth, carcass characteristics, and ruminal and blood characteristics of lambs fed concentrate diets. J. Anim. Sci. 76, 2025-2031.