Aplikasi Teknologi Nanopartikel Perak (AgNPs) dalam Air Minum dan Bentuk Kabut terhadap Kadar Amonia Ekskreta Broiler

Ones Putra Hulu, M Sihombing, R H Saputro, A Darmawan, Y Herbani


The purpose this study was evaluate the utilization of nanoparticles silver (AgNPs) on performance and ammonia concentration in broiler excreta.  This study used a factorial completely randomized design with 3x2 treatments and 4 replicates.  First factor (AgNPs at drinking water) was P1 = 0 ppm, P2 = 2 ppm, and P3 = 3 ppm and the  second factor Q (AgNPs by misty) was Q1 = 0 ppm and Q2 = 4 ppm.  The variables measured were excreta ammonia content, feed consumption, body weight gain, feed conversion ratio, mortality, temperature and relative humidity.  The results  showed that there was no interaction between AgNPs in drinking water and AgNPs in  its mist form on ammonia content.  AgNPs 4 ppm by misty also affected reduce FCR and body weight gain at week 3, also increased FCR at fourth week.  AgNPs in drinking water affected (P < 0.05) amonia content.  AgNPs 2 ppm in drinking water reduce until 11% amonia content.  AgNPs by misty also reduced (P< 0.05) amonia content.  AgNPs 0 ppm and 4 ppm by misty not created comfort temperature and relative humidity for broiler chicks. It is concluded that the addition of silver nanoparticles reduce excreta ammonia levels of broiler chickens.


amonia, humidity, misty, NanoSilver Particles (AgNPs), relatif and temprate

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Ahmadi F & Kurdestany AH. 2010. The impact of silver nano particles on growth performance, lymphoid organs and oxidative stress indicators in broiler chicks. Global Veterinaria. 5(6): 366-370

Al-Fataftah ARA & Abu-Dieyeh ZHM. 2007. Effect of chronic heat stress on broiler performance in Jordan. International Journal of Poultry Science. 6(1): 64-70

[AOAC]. 1988. Official Methods of Analisis. Edisi 13th. Washington, D.C. (US). Association of Official Analitical Chemist

Burnett WE. & Dondero NC. 1969. Microbial and chemical changes in poultry manure associated with decomposition and odour generation. Animal Waste Management. New York (US): Cornell University Conference on Agriculture Waste Management

Charles DR. 2002. Responses to the thermal environment in poultry environment problem: a guide to solution. Nottingham (UK). Nottingham University Press

Faunce T & Watal A. 2010. Nanosilver and global public health: international regulatory issues. Nanomedicine. 5(4):617-632

Feng QL, Wu J, Chen G Q, Cui F Z, Kim TN, & Kim JO. 2000. Mechanistic study of the antibacterial effect of silver ions on Escherichia coli and Staphylococcus aureus. Journal of Biomedical Materials Research. 52(4): 662-668

[GLP] General Laboratory Procedure. 1966. Report of Dairy Science. Madison (US). University of Wisconsin

Goel A, Bhanja SK, Mehra M, Majumar S, & Mandal A. 2017. In ovo silver nanoparticle supplementation for improving the post-hatch immunity status of broiler chickens. Journal of Animal Nutrition. 1(1): 11-12

Guzman MG, Jean D, & Stephan G. 2009. Synthesis of silver nanoparticles by chemical reduction method and their antibacterial activity. International Journal of Chemical and Biomolecular Engineering. 2(3):25-37

Karasawa Y, Ono T & Koli K. 1994. Inhibitory effect of penicillin on caecal urease activity in chicken fed on a low protein diet plus urea. British Poultry Science. 35(1): 157-160

Lesson S & Summer JD. 2000. Nutrition of the Chicken. 4th Edition. Canada (CA). University Books Canada

Mahendra R., Yadav, Alka, Gade, & Aniket. 2009. Nanoparticles as a new generation of antimicrobials. Biotechnology Advances. 27 (1):76-83

Montazer M, Hajimirzababa H, Rahimi MK, & Alibakhshi S. 2012. Durable antibacterial nylon carpet using colloidal nano silver. Fibres & Textiles in Eastern Europe. 4 (93): 96-101

Paramelle D, Sadovoy A, Gorelik S, Free P, Hobley J, & Fernig DG. 2014. A rapid method to estimate the concentration of citrate capped silver nanoparticles from uv-visible light spectrat. The Royal Society of Chemistry. 139 (19):4855-4861

Pineda L, Chwalibogs A, Sawosz E, Lauridsen C, Engberg R, Elnif J, Hotowy A, Sawosz F, Gao Y, Ali A & Moghaddan HS. 2012. Effect of silver nanoparticles on growth performance, metabolism and microbial profile of broiler chickens. Archives of Animal Nutrition. 66 (5): 416-429

Riza H, Wizna, Rizal Y, & Yusrizal. 2015. Peran probiotik dalam menurunkan amonia feses unggas. Jurnal Peternakan Indonesia. 17 (1): 19-26

Steel RGD & Torrie JH. 1993. Prinsip dan Prosedur Statistika: suatu Pendekatan Biometrik. Terjemahan: Bambang Sumantri. Jakarta (ID): PT Gramedia

Yeo J & Kim K. 1997. Effect of feeding diets containing an antibiotic, a probiotic, or yucca extract on growth and intestinal urease activity in broiler chicks. Poultry Science. 76 (2): 381-385

Yusrizal, Y 2012. Microbial and Oligosaccharides treatments of feces and slurry in reducing ammonia of the poultry farm. Media Peternakan. 35 (3) : 152-156

DOI: https://doi.org/10.29244/jintp.17.2.26-31


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Jurnal Ilmu Nutrisi dan Teknologi Pakan

Departemen Ilmu Nutrisi dan Teknologi Pakan, Fakultas Peternakan, Institut Pertanian Bogor
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ISSN : 0216-065X