Effect of Rumen Fluid Dosage and Fermentation Time on Dissolved Protein Levels of Vegetable Waste Silage for Vannamei Shrimp Feed
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https://doi.org/10.47667/ijpasr.v2i2.110Palabras clave:
Degree of Hydrolysis, Vegetable Waste, Rumen FluidResumen
Specifically, the goal of this research was to evaluate the dissolved protein content of vegetable waste generated during the incubation of rumen fluid for use in (Whiteleg) vannamei shrimp diet. The results of the analysis of the degree of protein hydrolysis of vegetable waste treated with the addition of rumen fluid enzymes and different fermentation times of rumen fluid revealed that the addition of rumen fluid enzymes and different fermentation times of rumen fluid had a statistically significant effect (p0.05) on the degree of protein hydrolysis of vegetable waste. But there was no significant difference in the length of fermentation time or the interaction between the dosage of rumen fluid and the length of time (p>0.05) between the two groups. Duncan's test of rumen fluid dosage revealed that the degree of hydrolysis at a 1 percent dose was considerably greater (p0.05) than at 2 percent and 3 percent doses, and that the degree of hydrolysis at a 3 percent dose was significantly lower than at 2 percent
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Angelidis, A. E., Crompton, L., Misselbrook, T., Yan, T., Reynolds, C. K., & Stergiadis, S. (2021). Equations to predict nitrogen outputs in manure, urine and faeces from beef cattle fed diets with contrasting crude protein concentration. Journal of Environmental Management, 295, 113074.
Basu, A., Vadanan, S. V., & Lim, S. (2018). A novel platform for evaluating the environmental impacts on bacterial cellulose production. Scientific reports, 8(1), 1-8.
Damodaran, S., & Parkin, K. L. (2017). Amino acids, peptides, and proteins. In Fennema’s food chemistry (pp. 235-356). CRC Press.
de Oliveira, C. F., Corrêa, A. P. F., Coletto, D., Daroit, D. J., Cladera-Olivera, F., & Brandelli, A. (2015). Soy protein hydrolysis with microbial protease to improve antioxidant and functional properties. Journal of Food Science and Technology, 52(5), 2668-2678.
e Silva, A. C. S., & Silveira, J. N. (2013). Correlation between the degree of hydrolysis and the peptide profile of whey protein concentrate hydrolysates: effect of the enzyme type and reaction time. American Journal of Food Technology, 8(1), 1-16.
Le, P. D., Aarnink, A. J. A., Jongbloed, A. W., Van der Peet-Schwering, C. M. C., Ogink, N. W. M., & Verstegen, M. W. A. (2008). Interactive effects of dietary crude protein and fermentable carbohydrate levels on odour from pig manure. Livestock Science, 114(1), 48-61.
Salwiczek, M., Nyakatura, E. K., Gerling, U. I., Ye, S., & Koksch, B. (2012). Fluorinated amino acids: compatibility with native protein structures and effects on protein–protein interactions. Chemical Society Reviews, 41(6), 2135-2171.
Torgbo, S., & Sukyai, P. (2018). Bacterial cellulose-based scaffold materials for bone tissue engineering. Applied Materials Today, 11, 34-49
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Derechos de autor 2021 International Journal Papier Advance and Scientific Review
Esta obra está bajo una licencia internacional Creative Commons Atribución-CompartirIgual 4.0.
