Journal of Veterinary and Animal Sciences

Volume: 55 Issue: 3

  • Open Access
  • Research Article

Evaluation of storage stability of poultry by-product meal incorporated fish feed under aerobic storage condition

Sahla Kannatti1*, A. Irshad1, Sanal Ebeneezar1, V.N. Vasudevan1, T. Sathu1 and Binsy Mathew2

1.Department of Livestock Products Technology, 2 Department of Veterinary Public Health, College of Veterinary and Animal Sciences, Mannuthy, Thrissur-680651, Kerala Veterinary and Animal Sciences University, Kerala, India

Year: 2024, Page: 558-564, Doi: https://doi.org/10.51966/jvas.2024.55.3.558-564

Received: March 11, 2024 Accepted: June 13, 2024 Published: Sept. 30, 2024

Abstract

The research focused on development of fish feed utilising poultry by-product meal (PBM) as a substitute for fish meal (FM) and evaluating its shelf life under aerobic packaging conditions. Initially, a basal diet (C) was formulated to meet the nutritional requirements for optimal growth of Tilapia by using FM as the major protein source. After analysing the nutritional composition of PBM, an isoproteinaceous diet (T) was formulated by replacing FM with PBM. The product was packed in HDPE bags and kept at room temperature and analysed for physico chemical and microbial characteristics for 45 days at weekly intervals. Moisture content of both C and T decreased significantly (p0.05) was found between C and T. The TBARS value of both C and T followed an increasing trend. This increase in C was not significant (p<0.01) between 28th and 35th day, and between 42nd and 45th day but that of T increased significantly (p<0.01) throughout the storage period. T consistently displayed the highest TBARS value during storage period. Tyrosine Value (TV) of both C and T also increased during storage and was significant (p<0.01) up to 42nd day of storage. C exhibited the highest TV throughout the storage period. Similarly, total viable count (TVC) of both C and T increased on storage. The increase in TVC for C was not significant (p<0.01) between 21st and 28th days, whereas that of T was significant (p<0.01) throughout the storage period. On 45th day, T exhibited highest count and was significantly different (p<0.01) from C. Throughout the 45-day storage period, no observable coliform count or yeast and mould count was noted in either C or T. The present study indicated that fish feed can be effectively prepared by utilising PBM and can be stored under room temperature up to 45 days.

Keywords: Poultry by-product meal, fish meal, fish feed, storage stability

References

AOAC [Analysis of Official Analytical Chemists]. 2016. Meat and meat products. In: Official Methods of Analysis of Analytical Chemists. (20th Ed.). Association of Official Analytical Chemists Inc, Rockville, Maryland, United States of America. 3172p.

APHA [American Public Health Association]. 2015. Compendium of methods for the microbiological examination of foods. (5th Ed.). American Public Health Association, APHA Press, Washington D.C. 995p.

Aydin, B., Gümüş, E. and Balci, B. 2015. Effect of dietary fish meal replacement by poultry by-product meal on muscle fatty acid composition and liver histology of fry of Nile tilapia, Oreochromis niloticus (Actinopterygii: Perciformes: Cichlidae). Acta Ichthyologica et Piscatoria. 45: 343–351.

BAHS [Basic Animal Husbandry Statistics]. 2023. Basic Animal Husbandry Statistics 2022. Ministry of Fisheries, Animal Husbandry and Dairying-2022, government of India, New Delhi, 172p.

Bureau, D.P., Harris, A.M. and Cho, C.Y. 1999. Apparent digestibility of rendered animal protein ingredients for rainbow trout. Aquaculture. 180: 345–358.

El Basuini, M.F., El‐Hais, A.M., Dawood, M.A.O., Abou‐Zeid, A.S., El‐Damrawy, S.Z., Khalafalla, M.S., Koshio, S., Ishikawa, M. and Dossou, S.J.A.N. 2017. Effects of dietary copper nanoparticles and vitamin C supplementations on growth performance, immune response and stress resistance of red sea bream, Pagrus major. Aquac. Nutr. 23: 1329-1340.

FAO [Food and Agriculture Organization]. 2015. Aquaculture Feed and Fertilizer Resources Information System, Rome, Italy. Available: https://www.fao.org/fishery/affris/en/

FAO [Food and Agriculture Organization]. 2023. Meat Market Review: Overview of global meat market and policy developments in 2022, Rome, Italy, 28p.

Fischer, A.R., De Jong, A.E., Van Asselt, E.D., De Jonge, R., Frewer, L.J. and Nauta, M.J. 2007. Food safety in the domestic environment: an interdisciplinary investigation of microbial hazards during food preparation. Risk Anal. Int. J. 27: 1065-1082.

Jayathilakan, K., Sultana, K., Radhakrishna, K. and Bawa, A.S. 2012. Utilization of by-products and waste materials from meat, poultry and fish processing industries: a review. J. Food Sci. Technol. 49: 278-293.

Karthik, P., Kulkarni, V. V. and Sivakumar, K. 2010. Preparation, storage stability and palatability of spent hen meal-based pet food. J. Food Sci. 47: 330-334.

Muduli, S., Champati, A., Popalghat, H.K., Patel, P. and Sneha, K.R. 2019. Poultry waste management: An approach for sustainable development. Int. J. Adv. Sci. Res. 4: 8-14.

Nengas, I., Alexis, M.N. and Davies, S.J. 1999. High inclusion levels of poultry meals and related by-products in diets for gilthead seabream Sparus aurata L. Aquaculture. 179:13-23.

Pame, K., Sathu, T., Vasudevan, V.N., Prajwal, S. and Gunasekaran, P. 2017. A study on the effect of physicochemical characteristics, palatability and storage quality of kibbles incorporated with slaughter house by-products for canine. Int. J. Livestock Res. 7: 228-237.

Porter, N.A., Caldwell, S.E. and Mills, K.A. 1995. Mechanisms of free radical oxidation of unsaturated lipids. Lipids. 30: 277-290.

Ravindran, V. and Blair, R. 1993. Feed resources for poultry production in Asia and the Pacific. III. Animal protein sources. World Poult. Sci. J. 49: 219-235.

Razak, N.A., Hamid, N.A. and Shaari, A.R. Effect of storage temperature on moisture content of encapsulated Orthosiphon stamineus spray-dried powder. In: AIP Conference Proceedings (Vol. 2030, No. 1); 29th and 30th April, 2018, Ho Chi Minh, Vietnam.

Salin, K.R., Arun, V.V., Mohanakumaran Nair, C. and Tidwell, J.H. 2018. Sustainable Aquafeed. In: Hai, F., Visvanathan, C., Boopathy, R. (eds.), Sustainable Aquaculture. Applied Environmental Science and Engineering for a Sustainable Future Series. Springer, Cham, pp. 123-151.

Shahidi, F. 2004. Seafood quality and safety: an overview. In: Shahidi, F. and Simpson, B.K. (ed.), Seafood quality and safety: Advances in the new millennium. Science Tech Publishing Company, Canada, pp. 1-5.

Snedecor, G.M. and Cochran, W.G. 1994. Statistical Methods. (8th Ed.). The Iowa State University, Ames, Iowa, 313p.

Strange, E.D., Benedict, R.C., Smith, J.L. and Swift, C.E. 1977. Evaluation of rapid tests for monitoring alterations in meat quality during storage: I. Intact meat. J. Food Prot. 40: 843-847.

Subasinghe, R., Soto, D. and Jia, J. 2009. Global aquaculture and its role in sustainable development. Rev. aquac. 1: 2-9.

Tacon, A.G. and Metian, M. 2015. Feed matters: satisfying the feed demand of aquaculture. Rev.  Fish. Sci. Aquac. 23: 1-10.

Wisman, E.L., Holmes, C.E. and Engel, R.W. 1958. Utilization of poultry by-products in poultry rations. Poult. Sci. 37: 834-838.

Witte, V.C., Krause, G.F. and Bailey, M.E. 1970. A new extraction method for determining 2‐thiobarbituric acid values of pork and beef during storage. J.  Food Sci. 35: 582-585.

Woodgate S.L. and van der Veen J.T. 2014. Fats and Oils-Animal Based. In: Clark S., Jung S., Lamsal B. (ed.), Food Processing: Principles and Applications. John Wiley and Sons, Chichester, UK, pp. 481–499.

Cite this article

Sahla K., Irshad A., Sanal E., Vasudevan V. N., Sathu T. and Bincy M. 2024. Evaluation of storage stability of poultry by-product meal incorporated fish feed under aerobic storage condition. J. Vet. Anim. Sci. 55 (3):558-564

Views
237
Downloads
107
Citations