Standardization of Dairy Products Through the Implementation of Pasteurization Technology and Aseptic Packaging
Abstract
In order to enhance the quality of goat's milk products and ensure their cleanliness and safety for consumption, it is imperative to standardize the product and enhance its quality through the implementation of pasteurization technology and the utilization of aseptic packaging. Moreover, this initiative aims to enhance the sustainable commercialization of Rokir Farm's dairy products. Products can generate financial gains for companies while providing individuals with high-quality dairy products. Additionally, these items can support government initiatives to ensure food security and address nutritional deficiencies. This activity entails a collaborative effort between universities and partners to address particular challenges partners encounter in product standardization. Other goat milk-producing farmer groups can utilize this activity as a model.
References
Astuti D. A., Sudarman, A. (2012). Dairy Goats in Indonesia: Potential, Opportunities and Challenges. Proceedings of the 1st Asia Dairy Goat Conference, 47-51.
Barba, F. J., Koubaa, M., Do Prado-Silva, L., Orlien, V., Sant Ana, A. D. S. (2017). Mild Processing Applied to the Inactivation of the Main Foodborne Bacterial Pathogens: A Review. Trends in Food Science & Technology, 66, 20–35.
BPS. (2022). Produksi Telur Unggas dan Susu Sapi Menurut Provinsi (kg).
Coolbear, T., Janin, N., Traill, R., Shingleton, R. (2022). Heat-Induced Changes in the Sensory Properties of Milk. International Dairy Journal, 126, 105199. https://doi.org/10.1016/j.idairyj.2021.105199
Coutinho, N. M., Silveira, M.R., Rocha, R.S., Moraes, J., Ferreira, M.V.S., Pimentel, T.C., Cruz, A.G. (2018). Cold Plasma Processing of Milk and Dairy Products. Trends in Food Science & Technology, 74, 56–68.
Gooch, E., Hoskin, R., & Law, J. (2017). China Dairy Supply and Demand. In A report from the Economic Research Service (pp. LDPM–282–201). Washington D.C., USA: United States Department of Agriculture.
Haenlein G. F. W. (2004). Goat Milk in Human Nutrition. Small Ruminant Research, 51(2), 155–163.
Hawkins, J., Ma, C. B., Schilizzi, S., & Zhang, F. (2018). China’s Changing Diet and Its Impacts on Greenhouse Gas Emissions: An Index Decomposition Analysis. Australian Journal of Agricultural and Resource Economics, 62(1), 45–64.
Huang, J.-k., Wei, W., Cui, Q., & Xie, W. (2017). The Prospects For China’s Food Security and Imports: Will China Starve the World Via Imports? Journal of Integrative Agriculture, 16(12), 2933–2944.
Makmum. (2021). http://ditjenpkh.pertanian.go.id/kementan-berkomitmen-kembangkan-produksi-susu-segar-dalam-negeri.
Sharabi, S., Okun, Z., Shpigelman, A. (2018). Changes in the Shelf Life Stability Of Riboflavin, Vitamin C and Antioxidant Properties of Milk After (Ultra) High Pressure Homogenization: Direct and Indirect Effects. Innovative Food Science & Emerging Technologies, 47, 161–169.
Stratakos, A. C., Inguglia, E. S., Linton, M., Tollerton, J., Murphy, L., Corcionivoschi, N., Koidis, A., Tiwari, B. K. (2019). Effect of High Pressure Processing on the Safety, Shelf Life and Quality of Raw Milk. Innovative Food Science & Emerging Technologies, 52, 325–333.
Tamime, A. Y. (2009). Milk Processing and Quality Management. John Wiley & Sons: Oxford, UK, 169–198.
Trilling, B, & Fadel, C. (2009). 21st Century Skills: Learning for Life in Our Times. San Farncisco: Josssey-Bass A Wiley Imprint.
Wang, H., Sun, Q., Liu, L., Zhang, S., Liang, X., Lu, J. (2012). Effect of Processing Temperature on Salts and Casein Colloid in Bovine Milk. Food Sciences, 33, 75–78.
Zagorska, J.; Galoburda, R.; Raita, S.; Liepa, M. (2021). Inactivation and Recovery of Bacterial Strains, Individually and Mixed, in Milk After High Pressure Processing. International Dairy Journal, 123, 105-147.
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