ارزیابی خصوصیات شیمیایی و قابلیت جذب منابع مختلف منگنز با استفاده از تکنیک قطعات وارونه روده و بررسی اثر سطوح و منابع مختلف منگنز بر عملکرد و پاسخ ایمنی جوجه‌های گوشتی

نوع مقاله : مقاله پژوهشی

نویسندگان

1 گروه علوم دامی دانشکده کشاورزی دانشگاه فردوسی مشهد، مشهد، ایران

2 گروه علوم دامی، دانشکده کشاورزی، دانشگاه فردوسی مشهد، مشهد، ایران

چکیده

آزمایشی با هدف تخمین زیست‌فراهمی و ارزیابی خصوصیات شیمیایی منابع آلی و معدنی منگنز شامل منگنز آلی، هیدروکسی کلراید منگنز و سولفات منگنز در جوجه‌های گوشتی با استفاده از تکنیک قطعات وارونه روده اجرا شد. در ابتدا، به‌منظور ارزیابی حلالیت و خصوصیات شیمیایی منابع منگنز در حلال‌های مختلف، از هرکدام از نمونه‌ها 1/0 گرم با سه تکرار نمونه‌برداری شد. در ادامه به‌منظور تعیین قابلیت جذب منابع منگنز از تکنیک قطعات وارونه روده استفاده شد. به این منظور، از جوجه خروس‌های 29 روزه که به‌مدت یک هفته (29-23روزگی) از جیره فاقد مکمل منگنز تغذیه شده بودند، استفاده شد و بعد از کشتار از ژژنوم و ایلئوم آن‌ها نمونه‌برداری شد. در ادامه، به‌منظور بررسی اثر سطوح و منابع مختلف منگنز بر صفات عملکردی و ایمنی جوجه‌های گوشتی از 600 قطعه جوجه خروس راس 308 در 12 تیمار شامل چهار سطح (35، 70، 105 و 140 میلی‌گرم بر کیلوگرم) و سه منبع (هیدروکسی کلراید، آلی و سولفات) منگنز استفاده شد. نتایج نشان داد که بیشترین حلالیت را منگنز آلی در سیتریک اسید 2 درصد (12/96 درصد) داشت و کمترین حلالیت منابع منگنز در آب دیونیزه بود. منبع هیدروکسی کلراید بیشترین حلالیت خود را در سیتریک اسید دو درصد با 02/83 درصد نشان داد. همچنین، بیشترین ابقای منگنز در ایلئوم (25/3 درصد) بود. منگنز آلی با 25/3 درصد به‌طور معنی‌داری قابلیت جذب بالاتری نسبت به منابع سولفات (99/1 درصد) و هیدروکسی کلراید (30/2 درصد) داشت. منابع منگنز اثر معنی‌داری بر صفات عملکردی نداشتند. ضریب تبدیل غذایی در سن 23-11 روزگی در تیمار دارای 35 میلی‌گرم بر کیلوگرم منبع هیدروکسی کلراید به‌طور معنی‌داری افزایش یافت. در خصوص ایمنی، تیمارهای آزمایشی اثر معنی‌داری بر پاسخ اولیه و ثانویه نداشتند. بنابراین، استفاده از منگنز آلی به‌دلیل ارزش جذب بالاتر توصیه می‌شود.

کلیدواژه‌ها

موضوعات


عنوان مقاله [English]

Evaluation of the Chemical Properties and Absorption Capacity of Different Manganese Sources using Everted Gut Sacs Technique and Their Effects on the Performance and Immune Response of Broiler Chickens

نویسندگان [English]

  • Farogh Kargar 1
  • Hasan Kermanshahi 2
  • Ali Javadmanesh 1
  • Reza Majidzadeh Heravi 1
1 Department of Animal Science, Faculty of Agriculture, Ferdowsi University of Mashhad, Mashhad, Iran.
2 Department of Animal Science, Faculty of Agriculture, Ferdowsi University of Mashhad, Mashhad, Iran.
چکیده [English]

Introduction:Manganese is an essential trace element that acts as an activating component of many crucial enzymes such as alginase and pyruvate carboxylase. It is involved in carbohydrate, lipid, and protein metabolism, as well as in vital biochemical reactions (Hassan et al., 2020). Additionally, manganese serves as a cofactor in the synthesis of chondroitin sulfate and plays a significant role in bone formation in broiler chickens (Mwangi et al., 2019). Moreover, manganese is vital for the antioxidant and immune systems of animals (Patra and Lalhriatpuii, 2020; Wang et al., 2018). In the production of broiler chickens, manganese sources commonly used include inorganic Mn (Mn sulfate, Mn carbonate and Mn oxide) and organic Mn (Mn chelated with amino acid and protein). Inorganic sources of manganese are cheaper, although they have low digestibility (Tufarelli and Laudadio, 2017; Yenice et al., 2015). Organic sources have excellent chemical stability and high absorption efficiency. They have not been widely used in poultry diet due to different quality levels of manufactured products, unpredictable effects and high cost (Tufarelli and Laudadio, 2017; Brooks et al., 2012). Therefore, it is important to assess new sources of manganese that have higher digestibility and lower cost. Manganese hydroxychloride is a group of minerals which solubility in water is minimal, but it becomes more soluble in acidic conditions in intestine (Wang et al., 2011). The purpose of this experiment was to investigate the different levels and sources of manganese in the diet of broiler chickens by investigating their effects on growth performance, immunity, the digestibility of different sources in different solvents, and the digestibility using the technique of Everted Gut Sacs.
Materials and Methods: Manganese sulfate, organic manganese, and manganese Hydroxychloride were obtained from Ariana company. In order to measurement of the amount of dry matter and ash, one gram in four repetitions was sampled from each of the sources. They were dried at 105°C for 12 hours and dry matter was calculated through subtraction. Then samples were transferred to the oven at 550°C for 16 hours and their ash content was determined. Finally, they were digested in hydrochloric acid and passed through Whatman filter paper No. 42. After making up to volume with mili-Q water, they were read by an atomic absorption device at a wavelength of 520 to 560 nm (AOAC, 1995; Williams, 1972). In order to evaluate the solubility, three samples (0.1 g) were prepared and dissolved in 100 ml of 2% citric acid, 0.4% hydrochloric acid and deionized water (Watson et al., 1970). For assessment ability to absorb minerals by the technique of Everted Gut Sacs, 180 one-day-old broilers of the Ross 308 commercial strain were fed from one to twenty-one days old with corn and soybean based (2018). On the 22nd day to the 28th day, they were fed with a diet free of manganese and on 29th day, they were starved for one day and night. Chickens were grouped into three treatments with Hydroxychloride, organic and manganese sulfate sources with 6 replications and 10 pieces per replication. Three parts were selected from each replication for the test steps (Feng et al., 2006). Samples prepared from jejunum and ileum in two buffers, Mis-Krebs and Tris-Krebs. In order to determine the relative bioavailability of different manganese sources, an experiment was conducted with 12 treatments included four different levels of manganese (35, 70, 105 and 140 mg/kg) with three different sources including Hydroxychloride, organic and sulfate.
Results and Discussion: The highest amount of dry matter of manganese was related to manganese sulfate (99.23%). The lowest was manganese hydroxychloride (92.58%). The highest ash percentage was related to manganese hydroxychloride with 86.14% and the lowest was related to organic manganese with 21.56%. The amount of manganese calculated after testing organic sources, hydroxychloride and sulfate was 5.64, 34.64 and 34.47% respectively. The organic form of manganese had the highest solubility in 2% citric acid and the lowest in deionized water with 96.12 and 34.14%, respectively. Manganese hydroxychloride also had the highest solubility in 2% citric acid solution. Manganese sulfate had the highest solubility in hydrochloric acid and the lowest solubility in deionized water. In general, manganese sulfate had the highest solubility in deionized water compared to the other two sources. Also, the highest solubility of organic manganese in 2% citric acid was 96.12% in the whole experiment. It has been reported in studies that binding minerals with proteins will be a weak chelate and when they are placed in solvents, their chelate breaks easily and dissolve (Cao et al., 2000). The results related to performance traits and primary and secondary response of antibody titer against sheep red blood cells (SRBC) showed that experimental treatments had no significant effect on them. 
Conclusion: The results showed that the highest solubility of the organic form of manganese was in citric acid (96.12%) and the lowest was in deionized water (34.13%). Manganese hydroxychloride had the highest solubility in 2% citric acid, while manganese sulfate had the highest solubility in 0.4% hydrochloric acid. Overall, manganese exhibited the highest solubility in hydrochloric acid and the lowest in deionized water. The results of the technique of inverted intestinal segments showed that the most absorption of manganese occurs in the ileum, and these results were in line with the results of other researchers who had performed this experiment in vitro and in vivo Among the experimental treatments, the highest absorption in the technique of inverted intestinal segments was related to the organic source of manganese, and the lowest was related to the form of sulfate, 3.25% and 1.99%, respectively. At the end, the use of organic manganese in broiler diet is recommended due to its high absorption level.

کلیدواژه‌ها [English]

  • Bioavailability
  • Broiler chicken
  • Everted Gut Sacs
  • Organic manganese
  • Performance traits

©2023 The author(s). This is an open access article distributed under Creative Commons Attribution 4.0 International License (CC BY 4.0), which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source.

  1. Allahdo, P., Ghodraty, J., Zarghi, H., Saadatfar, Z., Kermanshahi, H., & Edalatian Dovom, M. R. (2018). Effect of probiotic and vinegar on growth performance, meat yields, immune responses, and small intestine morphology of broiler chickens. Italian Journal of Animal Science17(3), 675-685.‏ https://org/10.1080/1828051X.2018.1424570
  2. (1995). Official Methods of Analysis, 16th ed. Association of Official Analytical Chemists, Arlington, VA. ‏‏ ‏Bai, S. P., Lu, L., Luo, X. G., & Liu, B. (2008). Kinetics of manganese absorption in ligated small intestinal segments of broilers. Poultry Science87(12), 2596-2604. https://doi.org/10.3382/ps.2008-00117.
  3. Berta, E., Andrásofszky, E., Bersényi, A., Glávits, R., Gáspárdy, A., & Fekete, S. G. (2004). Effect of inorganic and organic manganese supplementation on the performance and tissue manganese content of broiler chicks. Acta Veterinaria Hungarica52(2), 199-209.‏ https://org/10.1556/avet.52.2004.2.8.
  4. Black, J. R., Ammerman, C. B., Henry, P. R., & Miles, R. D. (1984). Biological availability of manganese sources and effects of high dietary manganese on tissue mineral composition of broiler-type chicks. Poultry Science63(10), 1999-2006. https://org/10.3382/ps.0631999 .
  5. Brooks, M. A., Grimes, J. L., Lloyd, K. E., Valdez, F., & Spears, J. W. (2012). Relative bioavailability in chicks of manganese from manganese propionate. Journal of Applied Poultry Research21(1), 126-130. https://org/10.3382/japr.2011-00331.
  6. Cao, J., Henry, P. R., Guo, R., Holwerda, R. A., Toth, J. P., Littell, R. C., & Ammerman, C. B. (2000). Chemical characteristics and relative bioavailability of supplemental organic zinc sources for poultry and ruminants. Journal of Animal Science78(8), 2039-2054.‏ https://org/10.2527/2000.7882039x .
  7. Conly, A. K., Poureslami, R., Koutsos, E. A., Batal, A. B., Jung, B., Beckstead, R., & Peterson, D. G. (2012). Tolerance and efficacy of tribasic manganese chloride in growing broiler chickens. Poultry Science91(7), 1633-1640.‏ https://org/10.3382/ps.2011-02056.
  8. EFSA panel on additives and products or substances used in animal feed (FEEDAP). (2016). Safety and efficacy of manganese hydroxychloride as feed additive for all animal species. EFSA Journal14(5), e04474. https://org/10.2903/j.efsa.2016.4474.
  9. Feng, Ji, Luo, X.G. Lu, L., Liu, B., & Yu, S.X. (2006). Effects of manganese source and calcium on manganese uptake by in vitro everted gut sacs of broiler’s intestinal segments. Poultry Science, 85, 1217–1225. https://org/10.1093/ps/85.7.1217.
  10. Halpin, K. M., Chausow, D. G., & Baker, D. H. (1986). Efficiency of manganese absorption in chicks fed corn-soy and casein diets. The Journal of Nutrition116(9), 1747-1751. https://org/10.1093/jn/116.9.1747.
  11. Hassan, S., Hassan, F. U., & Rehman, M. S. U. (2020). Nano-particles of trace minerals in poultry nutrition: Potential applications and future prospects. Biological Trace Element Research195, 591-612. https://doi.org/10.1007/s12011-019-01862-9.
  12. Jasek, A., Coufal, C. D., Parr, T. M., & Lee, J. T. (2019). Evaluation of increasing manganese hydroxychloride level on male broiler growth performance and tibia strength. Journal of Applied Poultry Research28(4), 1039-1047. https://org/10.3382/japr/pfz065.
  13. Jasek, A., Parr, T., Coufal, C. D., & Lee, J. T. (2020). Research note: Evaluation of manganese hydroxychloride in 45-wk-old white leghorn layers using yolk and shell manganese content. Poultry Science99(2), 1084-1087. https://org/10.1016/j.psj.2019.12.022.
  14. Ji, F., Luo, X. G., Lu, L., Liu, B., & Yu, S. Y. (2006). Effects of manganese source on manganese absorption by the intestine of broilers. Poultry Science85, 1947-1952. https://doi.org/10.1093/ps/85.11.1947.
  15. Kerkaert, H. R., Woodworth, J. C., DeRouchey, J. M., Dritz, S. S., Tokach, M. D., Goodband, R. D., & Manzke, N. E. (2020). Determining the effects of manganese source and level in diets containing high levels of copper on growth performance of growing-finishing pigs. Kansas Agricultural Experiment Station Research Reports6(10), 19. https://org/10.4148/2378-5977.8000.
  16. Leach, G. A., & Patton R.S. (1997). Analysis techniques for chelated minerals evaluated. Feedstuffs. 69, 13-15.
  17. Ledoux, D. R., Henry, P. R., Ammerman, C. B., Rao, P. V., & Miles, R. D. (1991). Estimation of the relative bioavailability of inorganic copper sources for chicks using tissue uptake of copper. Journal of Animal Science69(1), 215-222. https://org/10.2527/1991.691215x.
  18. Li, S., Luo, X. G., Lu, L., Crenshaw, T. D., Bu, Y. Q., Liu, B., Kuang, X., Shao, G. Z. & Yu, S. X. (2005). Bioavailability of organic manganese sources in broilers fed high dietary calcium. Animal Feed Science Technology, 123, 703-715. https://doi.org/10.1016/j.anifeedsci.2005.04.052..
  19. Li, S., Lu, L., Hao, S., Wang, Y., Zhang, L., Liu, S., & Luo, X. (2011). Dietary manganese modulates expression of the manganese-containing superoxide dismutase gene in chickens. The Journal of Nutrition141(2), 189-194. https://org/10.3945/jn.110.126680.
  20. Li, S., Luo, X., Liu, B., Crenshaw, T. D., Kuang, X., Shao, G., & Yu, S. (2004). Use of chemical characteristics to predict the relative bioavailability of supplemental organic manganese sources for broilers. Journal of Animal Science82(8), 2352-2363.‏ https://org/10.2527/2004.8282352x.
  21. Lu, L., Ji, C., Luo, X. G., Liu, B., & Yu, S. X. (2006). The effect of supplemental manganese in broiler diets on abdominal fat deposition and meat quality. Animal Feed Science and Technology129(1-2), 49-59.‏ https://doi.org/1016/j.anifeedsci.2005.12.005.
  22. Meng, T., Gao, L., Xie, C., Xiang, Y., Huang, Y., Zhang, Y., & Wu, X. (2021). Manganese methionine hydroxy analog chelated affects growth performance, trace element deposition and expression of related transporters of broilers. Animal Nutrition7(2), 481-487.‏ https://org/10.1016/j.aninu.2020.09.005.
  23. Moshtaghie, A. A., Badii, A. A., & Hassanzadeh, T. (2006). Investigation of manganese and iron absorption by rat everted gut sac. Pakistan Journal Biological Science. 9, 1346-1349. https://doi: 3923/pjbs.2006.1346.1349.
  24. Mwangi, S., Timmons, J., Ao, T., Paul, M., Macalintal, L., Pescatore, A., & Dawson, K. A. (2019). Effect of manganese preconditioning and replacing inorganic manganese with organic manganese on performance of male broiler chicks. Poultry science98(5), 2105-2113. https://org/10.3382/ps/pey564.
  25. National Research Council. (1994). Nutrient requirements of poultry. National Academies Press.
  26. Nollet, L., Van der klis, J., Lensing, M., & Spring P. (2007). The effect of replacing inorganic with organic trace minerals in broiler diets on productive performance and mineral excretion. Journal Apply Poultry Research, 16, 592-597. https://org/10.3382/japr.2006-00115.
  27. Ognik, K., Kozłowski, K., Stępniowska, A., Szlązak, R., Tutaj, K., Zduńczyk, Z., & Jankowski, J. (2019). The effect of manganese nanoparticles on performance, redox reactions and epigenetic changes in turkey tissues. Animal13(6), 1137-1144.‏ https://org/10.1017/S1751731118002653.
  28. Olgun, O. (2017). Manganese in poultry nutrition and its effect on performance and eggshell quality. World's Poultry Science Journal73(1), 45-56.‏ https://org/10.1017/S0043933916000891.
  29. Pacheco, B. H. C., Nakagi, V. D. S., Kobashigawa, E. H., Caniatto, A. R. D. M., & Faria, D. E. D. (2017). Dietary levels of zinc and manganese on the performance of broilers between 1 to 42 days of age. Brazilian Journal of Poultry Science19, 171-178.‏ https://org/10.1590/1806-9061-2016-0323.
  30. Pan, S., Zhang, K., Ding, X., Wang, J., Peng, H., Zeng, Q., & Bai, S. (2018). Effect of high dietary manganese on the immune responses of broilers following oral Salmonella typhimuriumBiological Trace Element Research181, 347-360. https://doi.org/10.1007/s12011-017-1060-9.
  31. Patra, A., & Lalhriatpuii, M. (2020). Progress and prospect of essential mineral nanoparticles in poultry nutrition and feeding—A review. Biological Trace Element Research197(1), 233-253. https://doi.org/10.1007/s12011-019-01959-1.
  32. Rubio Zapata, N. K. (2016). Effect of increasing levels of dietary zinc (Zn), manganese (Mn), and copper (Cu) from organic and inorganic sources on egg quality and egg Zn, Mn, and Cu content in laying hens. M.Sc., Louisiana State Univ. Zamorano.
  33. Spears, J. W. (2019). Boron, chromium, manganese, and nickel in agricultural animal production. Biological Trace Element Research188(1), 35-44. https://doi.org/10.1007/s12011-018-1529-1.
  34. Sun, Y., Geng, S., Yuan, T., Liu, Y., Zhang, Y., Di, Y., & Zhang, L. (2021). Effects of manganese hydroxychloride on growth performance, antioxidant capacity, Tibia parameters and manganese deposition of broilers. Animals11(12), 3470.‏ https://org/10.3390/ani11123470.
  35. Sunder, G. S., Panda, A. K., Gopinath, N. C., Raju, M. V., Rao, S. V. R., & Kumar, C. V. (2006). Effect of supplemental manganese on mineral uptake by tissues and immune response in broiler chickens. The Journal of Poultry Science43(4), 371-377.‏ https://org/10.2141/jpsa.43.371.
  36. Tufarelli, V., & Laudadio, V. (2017). Manganese and its role in poultry nutrition: an overview. Journal of Experimental Biology and Agricultural Sciences5(6), 749-754. https://doi: 18006/2017.5(6).749.754.
  37. Van der Zijpp, A., & Leenstra, F. (1980). Genetic analysis of the humoral immune response of White Leghorn chicks. Poultry Science 59(7): 1363-1369. https://org/10.3382/ps.0591363.
  38. Wang, C., Guan, Y., Lv, M., Zhang, R., Guo, Z., Wei, X., & Jiang, Z. (2018). Manganese increases the sensitivity of the cGAS-STING pathway for double-stranded DNA and is required for the host defense against DNA viruses. Immunity48(4), 675-687.
  39. Wang, F., Lu, L., Li, S., Liu, S., Zhang, L., Yao, J., & Luo, X. (2012). Relative bioavailability of manganese proteinate for broilers fed a conventional corn–soybean meal diet. Biological Trace Element Research146, 181-186. https://doi.org/10.1007/s12011-011-9238-z.
  40. Wang, Y. S., Zhang, J. P., & Gang, Y. (2011). Solubility and phase diagrams of hydroxyl manganese chloride. Transactions of Nonferrous Metals Society of China21(5), 1136-1140. https://org/10.1016/S1003-6326(11)60833-9.
  41. Watson, L. T., Ammerman, C. B., Miller, S. M., & Harms, R. H. (1970). Biological assay of inorganic manganese for chicks. Poultry Science49(6), 1548-1554.‏‏‏‏‏‏ https://org/10.3382/ps.0491548.
  42. Williams, T. R. (1972). Analytical methods for atomic absorption spectrophotometry (Perkin-Elmer Corp)‏.
  43. Yenice, E., Mızrak, C., Gültekin, M., Atik, Z., & Tunca, M. (2015). Effects of organic and inorganic forms of manganese, zinc, copper, and chromium on bioavailability of these minerals and calcium in late-phase laying hens. Biological Trace Element Research167, 300-307. https://doi.org/10.1007/s12011-015-0313-8.
  44. Yu, Y., Lu, L., Luo, X. G. & Liu, B. (2008). Kinetics of zinc absorption by in situ ligated intestinal loops of broilers involved in zinc transporters. Poultry Science, 87, 1146-1155. https://org/10.3382/ps.2007-00430.

 

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