Effects of Physical Modification of Nanostructure Aluminosilicate on Growth Performance, Carcass Traits and Blood Parameters of Broiler Chicken Challenged with Aflatoxin B1

Document Type : Poultry Nutrition

Authors

1 Department of Animal Science, Birjand Faculty of Agriculture, Birjand, Iran

2 Department of Animal Science, Faculty of Agriculture, University of Birjand, Birjand, Iran.

3 Department of Animal Sciences, Faculty of Agriculture, Birjand University, Birjand, Iran

4 Department of Chemistry, Birjand University, Birjand, Iran.

Abstract

Introduction: Fungi can grow in feed that maintained under normal temperature and high moisture condition. At the same condition, the fungi can produce mycotoxins in the feed. In poultry production, mycotoxicosis caused by key mycotoxins such as: Aflatoxin B1, Ochratoxin, T2toxin, Zearalenone and deoxynivalenol (DON, vomitoxin). Mycotoxins especially aflatoxin had undesirable influence on feed intake, body weight, feed conversion ratio and carcass characteristics. The Aflatoxin infected feed cause injuries on poultry's carcass especially liver and heart. Various aspects of the aflatoxicosis in poultry husbandry including effects on bird’s performance, digestion, metabolism, and organ function, metabolism of the toxin, and remnant of toxic residues to poultry products have been the subjects of several comprehensive reviews. The aflatoxin has vast economic losses in poultry industry via increase the mortality and reduces the growth performance. In order to reducing aflatoxin side effects, some ways were proposed such as inactivation of toxin, toxin adsorbent. Bentonite is the main toxin adsorbent. Bentonite can decrease the aflatoxin absorption from gut. Therefore this study was done to evaluate the effects of different levels of physical modified Nanostructure bentonite (PNB) on growth performance, carcass components and blood indices in broilers challenged by aflatoxin B1 (AFB1).
Material and Methods: One hundred and sixty day-old Ross 308 broiler chicks were bought from a great hatchery in South Khorasan, Iran. The birds were assigned to 20 experimental units with the same mean group body weight at initial experiment. The birds were reared for 35 days. The experiment was conducted in a completely randomized design with 5 treatments, 4 replicates and 8 birds in each. Experimental groups consisted of: negative control (C), positive control (basal diet with aflatoxin B1) (AF) and three level 0.25, 0.50 and 0.75 % of Physical modified Nanostructure bentonite added to basal diet with aflatoxin B1(positive control). The aflatoxin were added to starter and grower diets at 500 ppm and to finisher diets at 1000 ppm. At 21 and 35 days of age, one bird from each replicate was randomly selected and bled and blood parameters involved the concentration of cholesterol, triglyceride, LDL, HDL, total protein, and enzyme activity of alanine aminotransferase, aspartate aminotransferase, and lactate dehydrogenase were determined. One bird from each replicate of treatment were slaughtered and carcass components involved breast, thigh, abdominal fat, spleen, bursa of fabricius, and pancreas were weighed and the relative weight of organs were calculated. The data were analyzed by SAS software and general linear model (GLM) was used to analyze the data. The differences among means were determined by Tuckey's multiple range test.
Results and Discussion: The results showed that aflatoxin increased feed conversion ratio and reduced triglyceride as compared to control diet. The blood lipid was negatively influenced by infected aflatoxin diets in broilers. Supplementation of 0.25% Physical modified Nanostructure bentonite to the infected diet of broilers was significantly increased the feed intake, decreased the concentration of LDL (P<0.05). The lower relative weight of abdominal fat were observed in broilers fed diets contained aflatoxin and 0.25% Physical modified Nanostructure bentonite (PNB) (P<0.05). Birds fed infected diets and contained 0.75% PNB had higher triglyceride concentration compare to positive control. The ALT enzyme activity significantly increased in negative control treat compare to negative control and 0.50% PNB (P<0.05).In this research, the supplementation of Physical modified Nanostructure bentonite to broilers infected with aflatoxin reduced the undesirable effects of aflatoxin. As with previous research report that aflatoxin increased the feed conversion ratio and decreased the nutrient digestion and absorption. Inclusion of aflatoxin to broiler diets had undesirable effects on liver activity and liver injuries. The liver enzyme activities are indices to evaluate of liver function. The birds had higher liver enzyme activity, which may negatively affected by side effects of aflatoxin. The last literature were reported that the lower nutrient utilization might be a factor of the effects of the toxin on systemic metabolism rather than an effect on digestive functionality. Bentonite can adsorb the aflatoxin and reduce the side effects of them on broiler growth performance, digestive and liver function.
Conclusion: The result of this research showed that aflatoxin may decrease the performance parameters and addition of Physical modified Nanostructure bentonite reduced the negative effects of aflatoxin on performance and increased percentage of abdominal fat, therefore, the 0.5% Physical modified Nanostructure bentonite suggested to add in broiler diets contained aflatoxin.

Keywords

References

1. Asadifard, G., G. Tilaki, M. Ranjbar, M. Dini, A. Arab, M. Ghajavand, A. Kargari, and O. Moradi. 2006. Introduction to Nanotechnology Laboratory. Published by Nanotechnology Initiative Council Secretariat. (In Persian).
2. Azimi, J., M. A. Karimi Torshizi, A. A. Allame, and H. Ahari. 2013. The effect of additive two trade toxin binder and natural Zeolit to feed content aflatoxin B1 on performance and immune system of broiler chicks. Iranian Journal of Animal Science Research, 4(4): 292-297. (In Persian).
3. Bailey, C. A., G. W. Latimer, A. C. Barr, W. L. Wigle, A. U. Haq, J. E. Balthrop, and L. F. Kubena. 2006. Efficacy of Montmorillonite Clay (NovaSil PLUS) for Protecting Full-Term Broilers from Aflatoxicosis. Poultry Research, 15:198-206.
4. Bennett, J. W., and M. Klich. 2003. Mycotoxins. Clinical Microbiology Reviews, 16(3): 497-516.
5. Braun, R. D. 1987. Introduction to Instrumental Analysis, McGraw-Hill, New York.
6. Bridane, Y. O., R. Col, H. Basmacioglu, and H. Oguz. 2004. Effect of esterified glucomannan on aflatoxicosis: II) Serum biochemical-hematological and bone parameters. World's Poultry Congress. Turkey, Istanbul.
7. Charmley, L. L., H. L. Trenholm, and D. B. Prelusky. 1995. Mycotoxins: their origin, impact and importance; insight into common methods of control and elimination. PP. 41-63 In: T. Lyons and K. A. Jacques (Eds). Pp 41-63.
8. Chen, X., R. Murdoch, Q. Zhang, D. J. Shafer, and T. J. Applegate. 2016. Effects of dietary protein concentration on performance and nutrient digestibility in Pekin ducks during aflatoxicosis. Poultry Science, 95:834-841.
9. Dos Anjos, F. R., D. R. Ledoux, G. E. Rottinghaus, and M. Chimonyo. 2015. Efficacy of adsorbents (bentonite and diatomaceous earth) and turmeric (Curcuma longa) in alleviating the toxic effects of aflatoxin in chicks, British Poultry Science, 04:53.
10. Edrington, T. S., A. B. Sarr, L. F. Kubena, R. B. Harvey, and I. D. Phillips. 1996. Hydrated sodium calcium aluminosilicate (HSCAS). Acidic HSCAS and activated charcoal reduce urinary excretion of aflatoxin M1 in turkey poults. Lack of effect by activated charcoal on aflatoxicosis. Toxicology Letters, 89(2): 115-122.
11. Eraslan, G., D. Essiz, M. Mehmet akdogan, F. Sahindokuyucu, L. Altintas, and S. E. Hismiogullari. 2005. Effects of dietary aflatoxin and sodium bentonite on some hormones in broiler chickens. Bull Vet Inst Pulawy, 49: 93-96.
12. Friedewald, W. T., R. I. Levy, and D. S. Fredrickson. 1972. Estimation of the concentration of low-density lipoprotein cholesterol in plasma, without use of the preparative ultracentrifuge. Clinical Chemistry, 18:499-502.
13. Ghahri, H., A. Solimannezhad, D. Mohajeri, and A. Zakir. 2010 .The effect of Sodium Bentonite, Yeast cell wall and humic acid of reducing kidney damage aflatoxin and blood parameters of broiler chicks. Veterinary Journal of Islamic Azad University of Tabriz, 4(3): 907-914. (In Persian).
14. Gholampour Azizi, I., and A. Khosravi. 2007. Aflatoxin Pervention and Immunoassay.Reasearch Unit of Islamic Azad University Babol, Mabas Publisher. (In Persian).
15. Golestani Fard, F., M. A. Bahrevar, and E. Salahi. 2013. The methods of indentification and analysis of material. Published by Elmo-Sanaat Iran University. (In Persian).
16. He, Q. R., J. Kim, and R. P. Sharma. 2004. Silymarin protects agaist liver damage in BALB/c mice exposed to ftimonisin B-1 despite increasing accumulation of free sphingoid bases. Toxicology Science, 80(2): 335-342.
17. Hussein, H. S., and J. M. Brasel. 2001. Toxicity, metabolism and impact of mycotoxins on humans and animals. Toxicology, 167: 101-134.
18. Kermanshahi, H., A. R. Hazegh, and N. Afzali. 2009. Efeect of Sodium Bentonite in Broiler Chickens Fed Diets Contaminated with Aflatoxin B1. Journal of Animal and Veterinary Advances, 8(8): 1631-1636.
19. Leeson, S., G. Diaz, and J. D. Summers. 2001. Poultry Metabolic Disorders and Mycotoxins. Translaters to Persian: Jafari, R, A., Mayahi. M. Publisher Shahid Chamran University.
20. Lemke, S. L., S. E. Ottinger, K. Mayura, C. L. Ake, K. Pimpukdee, N. Wang, and T. D. Phillips. 2001. Development of a multi-tiered approach to the in vitro prescreening of clay-based enters sorbent. Animal Feed Science and Technologies, 93: 17-29.
21. Marashi, P., S. Kaviani, H. Sarpoolaky, and A. R. Zolfaghari. 2004. Electron Microscopes and new analysis methods as nano world investigation tools. Published by Elmo-Sanaat Iran University. (In Persian).
22. Masumy, A. 1995. Instrumental Chemistry. Islamic Azad University, North Tehran. (In Persian).
23. Mojtahedi, M. 2013. Identification of nanostructured and nanoporous bentonite adsorbents and their efficiency on aflatoxin b1 detoxification In Vitro and In Vivo. PhD thesis, Ferdowsi University of Mashhad, Iran. (In Persian).
24. Mulder, I., A. L. Barrientos, M. G. Velazquez, G. N. Tenorio Arvide, and J. B. Dixon. 2008. Smectite clay sequestration of aflatoxin B1: particle size and morphology. Clays and Clay Minerals, 56(5): 558-570(13).
25. Pasha, T. N., M. U. Farooq, F. M. Khattak, M. A. Jabbar, and A. D. Khan. 2007. Effectiveness of sodium bentonite and two commercial products as aflatoxin absorbents in diets for broiler chickens. Animal Feed Science and Technology, 132: 103-110.
26. Phillips, T. D., L. F. Kubena, R. B. Harvey, D. R. Taylor, and N. D. Heidelbaugh. 1988. Hydrated sodium calcium aluminosilicate: A high affinity sorbent for aflatoxin. Poultry Science, 67: 243-247.
27. Pier, A. C. 1973. Effects of aflatoxin on immunity. Journal of the American Veterinary Medical Association. 163: 1268-1269.
28. Raju, M. V. L. N., and G. Devegowda. 2000. Influence of esterified-glucomannan on performance and organ morphology, serum biochemistry and haematology in broilers exposed to individual and combined mycotoxicosis (aflatoxin, ochratoxin and T-2 toxin). British Poultry Science, 41(5): 640-650.
29. Razmara, M., and M. Ghafoori. 2006. Fundamentals of clay mineralogy, Published by Ferdowsi University, Iran. (In Persian).
30. Richard, J. L., A. C. Pier, R. D. Stubblefield, O. L. Shotwell, R. L. Lyon, and R. C. Cutlip. 1983. Effect of feeding corn naturally contaminated with aflatoxin on feed effiency, on physiologic, immunologic, and pathologic changes and on tissue residues in steers.
31. Ritter, A. C., M. Hoeltz, and I. B. Noll. 2011. Toxigenic potential of Aspergillus flavus tested in different culture conditions. Ciência e Tecnologia de Alimentos Campinas, 31(3): 623-628.
32. Rosa, C. A. R., R. Miazzo, C. Magnoli, M. Salvano, S. M. Chiacchiera, S. Ferrero, M. Saenz, E. C. Q. Carvallho, and A. Dalcero. 2001. Evaluation of the efficacy of bentonite from the south of Argentina to ameliorate the toxic effects of aflatoxin in broilers. Poultry Science, 80: 139-144.
33. Schell, T., M. Lindemann, E. Kornegay, and D. Blodgett. 1993. Effects of feeding aflatoxin-contaminated diets with and without clay to weanling and growing pigs on performance, liver function, and mineral metabolism. Journal of Animal Science, 71: 1209-1218.
34. Shi, Y. H., Z. R. Xu, J. L. Feng, and C. Z. Wang. 2006. Efficacy of modified montmorillonite nanocomposite to reduce the toxicity of aflatoxin in broiler chicks. Animal Feed Science and Technology, 129:138-148.
35. Shotwell, O. L., C. W. Hesseltine, R. D. Stubblefield, and W. G. Sorenson. 1966. Production of aflatoxin on rice. Applied Microbiology, American Society of Microbiology, 14(3): 425-8.
36. Velazquez, A. L. B. 2011. Texas bentonites as amendments of aflatoxin-contaminated poultry feed. M.Sc. thesis of Texas A&M University.
37. Yalagod, S. G. 2014. Studies on low levels of aflatoxin induced immunotoxicity in broiler chicken and its amelioration. PhD, thesis, Karanataka Veterinary, Animal and Fisheries Sciences University, Bidar Department of Veterinary Pathology, Veterinary College. Bangalor.
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Iranian Journal of Animal Science Research
Volume 10, Issue 4 - Serial Number 36
December 2019
Pages 489-500

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History

  • Receive Date: 26 May 2017
  • Accept Date: 26 May 2017
  • First Publish Date: 22 December 2018

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