Effect of Dietary Supplementation of Nano Zinc on Performance, Egg Characteristics, Sperm Quality and Hatching Parameters in Breeding Quails

Yıl 2019, Cilt: 9 Sayı: 4, 2390 - 2397, 01.12.2019

Onur Tatlı Ömer Sevim Solmaz Karaarslan Eren Kuter Mehmet Kaya Ehsan Karimiyan Khamseh Uğur Uçan Bekir Hakan Köksal Özcan Cengiz Ahmet Gökhan Önol

https://doi.org/10.21597/jist.555088

Cited By: 2

Öz

In this study, the effects of requirement level (60 mg/kg) of nano zinc supplementation (46 mg/kg) of breeding quail rations on egg production, weight gain, egg quality characteristics, sperm quality, hatching parameters and liver were determined. 10 week old quails (Coturnix coturnix Japonica) were divided into two groups: control and experiment with 10 replicates were formed under each group that having one male four female in each, a total of 100 (20 male and 80 female) quails were used in the study. At the end of 10 weeks trial period, supplementation of nano zinc does not have any significant effect on weight gain, feed consumption and egg production. In terms of egg quality characteristics, it was seen that the addition of nano zinc had a significantly decrease on egg yolk color (P<0.001) and the other parameters were not affected. Sperm morphological abnormality rates were observed similar to each other, and in the control and treatment group, they were detected as 32.2% and 30.0% respectively. It was revealed that the nano zinc was positively influenced on the fertility rate, but the effect on the hatchability was found lower and early embryonic mortality rate was found higher (P<0.05) than control group. Histopathologic evaluation of the liver revealed that there was severe lipoidosis in the liver in the nano zinc supplemented group. As a result; nano zinc oxide addition at the recommended level had no effect on performance, but had negative effects on liver, egg yolk color, hatching and early embryonic mortality rate.

Anahtar Kelimeler

Nano zinc, quail, egg quality, sperm quality, hatching parameters

Damızlık Bıldırcın Rasyonlarına Katılan Nano Çinkonun Performans, Yumurta Özellikleri, Sperm Kalitesi ve Kuluçka Parametreleri Üzerine Etkisi

Öz

Yapılan bu araştırmada, damızlık bıldırcın rasyonlarına gereksinim düzeyini (60 mg/kg) sağlayacak şekilde nano çinko oksit katılmasının (46 mg/kg) yumurta verimi, canlı ağırlık, yumurta kalite özellikleri, sperm kalitesi, kuluçka parametreleri ve karaciğer üzerine olan etkileri incelenmiştir. Çalışmada 20 erkek ve 80 dişi olmak üzere toplam 100 adet bıldırcın (Coturnix coturnix Japonica) kullanılmış, 10 haftalık yaşta olan hayvanlar kontrol ve deneme olmak üzere iki gruba ayrılmış ve her grupta her biri bir erkek dört dişi içeren 10’ar adet alt grup oluşturulmuştur. 10 hafta sürdürülen deneme sonunda, damızlık bıldırcın rasyonlarına nano çinko oksit katılmasının canlı ağırlık, yem tüketimi ve yumurta verimi üzerine herhangi bir etkisinin olmadığı belirlenmiştir. Yumurta kalite özellikleri bakımından ise rasyona nano çinko oksit katılmasının yumurta sarısı rengi üzerinde önemli düzeyde (P<0.001) azalma meydana getirdiği, diğer parametrelerin ise etkilenmediği görülmüştür. Sperm morfolojik bozukluk oranları ele alındığında değerlerin birbirlerine yakın olduğu gözlenmiş, kontrol ve deneme grubunda sırasıyla %32.2 ve 30.0 olarak tespit edilmiştir. Rasyona katılan nano çinkonun döllülük oranı üzerine olumlu etkisinin olduğu (P<0.001), ancak yumurtadan çıkış oranında düşüş (P<0.05) meydana getirdiği ve erken embriyonik ölüm oranını artırdığı (P<0.05) tespit edilmiştir. Karaciğer dokusunda yapılan histopatolojik değerlendirmede nano çinko oksit katılan grupta karaciğerde şiddetli düzeyde yağlanma meydana geldiği belirlenmiştir. Sonuç olarak; önerilen düzeyde nano çinko oksit katılmasının performans üzerine etkisinin olmadığı, sarı rengi, çıkım ve erken embriyonik ölüm oranı ile karaciğer üzerine olumsuz etkilerinin olduğu ortaya konmuştur.

Anahtar Kelimeler

Nano çinko, bıldırcın, yumurta kalitesi, sperm kalitesi, kuluçka parametreleri

Kaynakça

• Abbasi M, Dastar B, Afzali N, Shams Shargh MI, Hashemi SR, 2017. Zinc Requirements of Japanese Quails (Coturnix coturnix Japonica) by Assessing Dose- Evaluating Response of Zinc Oxide Nano-Particle Supplementation. Poultry Science Journal, 5:131-143.
• Abd El-Samee LD, El-Wardany I, Ali NG, Abo-El-Azab OM, 2012. Egg Quality, Fertility and Hatchability of Laying Quails fed Diets Supplemented with Organic Zinc, Chromium Yeast or Mannan Oligosaccharides. International Journal of Poultry Science, 11:221-224.
• Ahmadi F, Ebrahimnezhad Y, Maheri Sis N, Ghalehkandi JG, 2013. The Effect of Zinc Oxide Nanoparticles on Performance, Digestive Organs and Serum Lipid Concentrations in Broiler Chickens During Starter Period. International Journal of Biosciences, 3:23-29.
• Ahmed AMH, Rodriguez-Navarro AB, Vidal ML, Gautron J, García-Ruiz JM, Nys Y, 2005. Changes in Eggshell Mechanical Properties, Crystallographic Texture and in Matrix Proteins Induced by Moult in Hens. British Poultry Science, 46:268-279.
• Amen MHM, Al-Daraji HJ, 2011. Effect of Dietary Supplementation with Different Level of Zinc on Sperm Egg Penetration and Fertility Traits of Broiler Breeder Chicken. Pakistan Journal of Nutrition, 10:1083-1088.
• Bancroft JD, Stevens A, Turner DR, 1996. Theory and Practice of Histological Techniques. Churchill Livingstone, London, United Kingdom.
• Bunglavan SJ, Garg AK, Dass RS, Shrivastava S, 2014. Use of Nanoparticles as Feed Additives to Improve Digestion and Absorption in Livestock. Livestock Research International, 2:36-47.
• Chen H, Weiss J, Shahidi F, 2006. Nanotechnology in Nutraceuticals and Functional Foods. Food Technology, 3:30-36.
• Cousins RJ, Liuzzi JP, Lichten LA, 2006. Mammalian Zinc Transport, Trafficking, and Signals. Journal of Biological Chemistry, 281:24085-24089.
• Fazilati M, 2013. Investigation Toxicity Properties of Zinc Oxide Nanoparticles on Liver Enzymes in Male Rat. European Journal of Experimental Biology, 3:97-103.
• Feng M, Wang ZS, Zhou AG, Ai DW, 2009. The Effects of Different Sizes of Nanometer Zinc Oxide on the Proliferation and Cell Integrity of Mice Duodenum-Epithelial Cells in Primary Culture. Pakistan Journal of Nutrition, 8:1164-1166.
• Hong JS, Park MK, Kim MS, Lim JH, Park GJ, Maeng EH, Shin JH, Kim MK, Jeong J, Park JA, Kim JC, Shin HC, 2014. Prenatal Development Toxicity Study of Zinc Oxide Nanoparticles in Rats. International Journal of Nanomedicine, 9:159-171.
• Huang S, Wang L, Liu L, Hou Y, Li L, 2015. Nanotechnology in Agriculture, Livestock and Aquaculture in China. A Review. Agronomy for Sustainable Development, 35:369-400.
• Jo E, Seo G, Kwon JT, Lee M, Lee BC, Eom I, Kim P, Choi K, 2013. Exposure to Zinc Nanoparticles Affects Reproductive Development and Biodistribution in Offspring Rats. The Journal of Toxicological Sciences, 38:525-530.
• Khoobbakht Z, Roostaei-Ali Mehr M, Mohammadi M, Sohani MM, Mohammadghasemi F, 2018. Abnormalities in Unhatched Chicks of Japanese Quails Fed with Zinc Oxide Nanoparticles. Journal of Dairy and Veterinary Sciences, 5:1-3.
• Kutlu HR, Şahin A, 2017. Kanatlı Beslemede Güncel Çalışmalar ve Gelecek için Öneriler. Hayvansal Üretim, 58:66-79.
• McDowell LR, 2003. Minerals in Animals and Human Nutrition. 2nd Edition. Elsevier Science, BV Amsterdam, Netherlands.
• Mishra A, Swain RK, Mishra SK, Panda N, Sethy K, 2014. Growth Performance and Serum Biochemical Parameters as Affected by Nano Zinc Supplementation in Layer Chicks. Indian Journal of Animal Nutrition, 31:384-388.
• Mohammadi F, Ahmadi Fi Amiri AM, 2015. Effect of Zinc Oxide Nanoparticles on Carcass Parameters, Relative Weight of Digestive and Lymphoid Organs of Broiler Fed Wet Diet During the Strater Period. International Journal of Biosciences, 6:389-394.
• Mohapatra P, Swain RK, Mishra SK, Behera T, Swain P, 2014. Effects of Dietary Nano-Selenium Supplementation on the Performance of Layer Grower Birds. Asian Journal of Animal and Veterinary Advances, 9:641-652.
• Monira KN, Salahuddin M, Miah G, 2003. Effect of Breed and Holding Period on Egg Quality Characteristics of Chicken. International Journal of Poultry Science, 2:261-263.
• NRC: National Research Council, 1994. Nutrient Requirements of Poultry. 9th Revised Edition, National Academy Press, Washington, USA.
• Özdamar K, 2004. Paket Programlama ile İstatistiksel Veri Analizi. 2. Basım, Kaan Kitabevi, Eskişehir, Türkiye.
• Patil SS, Kore KB, Kumar P, 2012. Nanotechnology and Its Applications in Veterinary and Animal Science. Veterinary World, 2:475-477.
• Sirirat N, Lu JJ, Hung ATY, Chen SY, Lien TF, 2012. Effects Different Levels of Nanoparticles Chromium Picolinate Supplementation on Growth Performance, Mineral Retention and Immune Responses in Broiler Chickens. Journal of Agriculture Science, 4:48-58.
• Suttle NF, 2010. Mineral Nutrition of Livestock. 4th Edition, CABI, Wallingford, Oxfordshire, United Kingdom.
• Swain SS, Rajendran D, Rao SBN, Dominic G, 2015. Preparation and Effects of Nano Mineral Particle Feeding in Livestock: A review. Veterinary World, 8:888-891.
• Talebi AR, Khorsandi L, Moridian M, 2013. The Effect of Zinc Oxide Nanoparticles on Mouse Spematogenesis. Journal of Assisted Reproductionand Genetics, 30:1203-1209.
• Wang ZL, 2000. Characterization of Nanophase Material. Wiley-VCH Verlag GmbH: Weinheim, Germany.
• Yang X, Shao H, Liu W, Gu W, Shu X, Mo Y, Chen X, Zhang Q, Jiang M, 2015. Endoplasmic Reticulum Stress and Oxidative Stress are Involved in ZnO Nanoparticle-Induced Hepatotoxicity. Toxicology Letters, 234:40-49.
• Zhao Y,Li L, Zhang PF, Liu XQ, Zhang WD, Ding ZP, Wang SW, Shen W, Min LJ, Hao ZH, 2016. Regulation of Egg Quality and Lipids Metabolism by Zinc Oxide Nanoparticles. Poultry Science, 95:920-933.