[KSCI] Korea Science Citation Index Service

http://dx.doi.org/10.5713/ajas.2013.r.02

Feed Energy Evaluation for Growing Pigs

Kil, D.Y. (Department of Animal Science and Technology, Chung-Ang University)
Kim, B.G. (Department of Animal Science and Technology, Konkuk University)
Stein, H.H. (Department of Animal Sciences, University of Illinois)

Publication Information

Asian-Australasian Journal of Animal Sciences / v.26, no.9, 2013 , pp. 1205-1217 More about this Journal

Abstract

Pigs require energy for maintenance and productive purposes, and an accurate amount of available energy in feeds should be provided according to their energy requirement. Available energy in feeds for pigs has been characterized as DE, ME, or NE by considering sequential energy losses during digestion and metabolism from GE in feeds. Among these energy values, the NE system has been recognized as providing energy values of ingredients and diets that most closely describes the available energy to animals because it takes the heat increment from digestive utilization and metabolism of feeds into account. However, NE values for diets and individual ingredients are moving targets, and therefore, none of the NE systems are able to accurately predict truly available energy in feeds. The DE or ME values for feeds are important for predicting NE values, but depend on the growth stage of pigs (i.e., BW) due to the different abilities of nutrient digestion, especially for dietary fiber. The NE values are also influenced by both environment that affects NE requirement for maintenance ( $NE_m$ ) and the growth stage of pigs that differs in nutrient utilization (i.e., protein vs. lipid synthesis) in the body. Therefore, the interaction among animals, environment, and feed characteristics should be taken into consideration for advancing feed energy evaluation. A more mechanistic approach has been adopted in Denmark as potential physiological energy (PPE) for feeds, which is based on the theoretical biochemical utilization of energy in feeds for pigs. The PPE values are, therefore, believed to be independent of animals and environment. This review provides an overview over current knowledge on energy utilization and energy evaluation systems in feeds for growing pigs.

Keywords

Energy Utilization; Feed Energy Systems; Pigs;

Citations & Related Records

Reference

1	Shi, X. S. and J. Noblet. 1993. Contribution of the hindgut to digestion of diets in growing pigs and adult sows: effect of diet composition. Livest. Prod. Sci. 34:237-252. DOI ScienceOn
2	Stewart, L. L., D. Y. Kil, F. Ji, R. B. Hinson, A. D. Beaulieu, G. L. Allee, J. F. Patience, J. E. Pettigrew, and H. H. Stein. 2013. Effects of dietary soybean hulls and wheat middlings on body composition, nutrient and energy retention, and the net energy of diets and ingredients fed to growing and finishing pigs. J. Anim. Sci. 91:2756-2765. DOI ScienceOn
3	Tess, M. W., G. E. Dickerson, J. A. Nienaber, and C. L. Ferrell. 1984. The effects of body composition on fasting heat production in pigs. J. Anim. Sci. 58:99-110.
4	Tess, M. W., G. E. Dickerson, J. A. Nienaber, and C. L. Ferrell. 1986. Growth, development and body composition in three genetic stocks of swine. J. Anim. Sci. 62:968-979.
5	Thonney, M. L., R. W. Touchberry, R. D. Goodrich, and J. C. Meiske. 1976. Intraspecies relationship between fasting heat production and body weight: A reevaluation of W.75. J. Anim. Sci. 43:692-704.
6	Rijnen, M. M. J. A. 2003. Energetic utilization of dietary fiber in pigs. Ph.D. Thesis, University of Wageningen, Wageningen, the Netherlands.
7	Noblet, J. and J. M. Perez. 1993. Prediction of digestibility of nutrients and energy values of pig diets from chemical analysis. J. Anim. Sci. 71:3389-3398.
8	Noblet, J., X. S. Shi, and S. Dubois. 1994b. Effect of body weight on net energy value of feeds for growing pigs. J. Anim. Sci. 72:648-657.
9	Noblet, J. and J. van Milgen. 2004. Energy value of pig feeds: Effect of pig body weight and energy evaluation system. J. Anim. Sci. 82(E. Suppl.):E229-E238.
10	NRC. 1998. Nutrient requirements of swine. 10th rev. Ed. Natl. Acad. Press, Washington, DC.
11	NRC. 2012. Nutrient requirements of swine. 11th rev. Ed. Natl. Acad. Press, Washington, DC.
12	Nyachoti, C. M., R. T. Zijlstra, C. F. M. de Lange, and J. F. Patience. 2004. Voluntary feed intake in growing-finishing pigs: A review of the main determining factors and potential approaches for accurate predictions. Can. J. Anim. Sci. 84:549-566. DOI ScienceOn
13	Oresanya, T. F., A. D. Beaulieu, and J. F. Patience. 2008. Investigations of energy metabolism in weanling barrows: The interaction of dietary energy concentration and daily feed (energy) intake. J. Anim. Sci. 86:348-363.
14	Payne, R. L. 2006. The net energy system in swine- How can it help you? Feedstuffs. March. 27:16-20.
15	Patience, J. F. and A. D. Beaulieu. 2005. The merits, benefits, and challenges of adopting the net energy system in a North American context. In: Proc. 66th Minnesota Nutr. Conf. Tech. Symp.: Future of corn in animal feed. September 20-21. St. Paul. MN. pp. 134-149.
16	Quiniou, N., S. Dubois, and J. Noblet. 1995. Effect of dietary crude protein level on protein and energy balances in growing pigs: comparison of two measurement methods. Livest. Prod. Sci. 41:51-61. DOI ScienceOn
17	Reynolds, C. K. 2000. Measurement of energy metabolism. In: Feeding Systems and Feed Evaluation Models (Ed. M. K. Theodorou, and J. France). CAB International, Oxon, U.K. pp. 87-107.
18	McDonald, P., R. A. Edwads, J. F. D. Greenhalgh, and C. A. Morgan. 2002. Evaluation of foods: energy content of foods and the partition of food energy within the animal. In: Animal Nutrition. 5th Ed. (Ed. P. McDonals, R. A. Edwads, J. F. D. Greenhalgh, and C. A. Morgan). Pearson, UK. pp. 263-291.
19	Mayes, P. A. 2000. Bioenergetics: The role of ATP. In: Harper's Biochemistry, 25th Ed. (Ed. R. K Murry, D. K. Granner, P. A. Mayes, and V. W. Rodwell). McGraw-Hill, New York, NY. pp. 123-129.
20	Moehn, S., J. Atakora, and R. O. Ball. 2005. Using net energy for diet formulation: Potential for the Canadian pig industry. Adv. Pork Prod. 16:119-129.
21	Morgan, D. J., D. J. A. Cole, and D. Lewis. 1975. Energy values in pig nutrition: I. The relationship between digestible energy, metabolizable energy and total digestible nutrient values of a range of feedstuffs. J. Agric. Sci. (Camb.). 84:7-17. DOI
22	Noblet, J. 1996. Digestive and metabolic utilization of dietary energy in pig feeds: Comparison of energy systems. In: Recent Advances in Animal Nutrition (Ed. P. C. Garnsworthy, J. Wiseman and W. Haresign). Nottingham University Press, Nottingham, U.K. pp. 207-231.
23	Noblet, J. 2007. Recent developments in net energy research for swine. Adv. Pork Prod. 18:149-156.
24	Noblet, J., H. Fortune, X. S. Shi, and S. Dubois. 1994a. Prediction of net energy value of feeds for growing pigs. J. Anim. Sci. 72:344-353.
25	Noblet, J. and Y. Henry. 1993. Energy evaluation systems for pig diets: a review. Livest. Prod. Sci. 36:121-141. DOI ScienceOn
26	Noblet, J., C. Karege, and S. Dubois. 1991. Influence of growth potential on energy requirements for maintenance in growing pigs. In: Energy Metabolism of Farm Animals (Ed. C. Wenk and M. Boessinger). EAAP Publication, Zurich, Switzerland. pp. 107-110.
27	Noblet, J., C. Karege, S. Dubois, and J. van Milgen. 1999. Metabolic utilization of energy and maintenance requirements in growing pigs: Effects of sex and genotype. J. Anim. Sci. 77:1208-1216.
28	Just, A. 1982. The net energy value of balanced diets for growing pigs. Livest. Prod. Sci. 8:541-555. DOI ScienceOn
29	Just, A., H. Jorgensen, and J. A. Fernandez. 1983. Maintenance requirement and the net energy value of different diets for growth in pigs. Livest. Prod. Sci. 10:487-506. DOI ScienceOn
30	Kil, D. Y. 2008. Digestibility and energetic utilization of lipids by pigs. Ph.D. Thesis, University of Illinois, Urbana, USA.
31	Kil, D. Y., F. Ji, L. L. Stewart, R. B. Hinson, A. D. Beaulieu, G. L. Allee, J. F. Patience, J. E. Pettigrew, and H. H. Stein. 2011. Net energy of soybean oil and choice white grease in diets fed to growing and finishing pigs. J. Anim. Sci. 89:448-459. DOI ScienceOn
32	Kil, D. Y., F. Ji, L. L. Stewart, R. B. Hinson, A. D. Beaulieu, G. L. Allee, J. F. Patience, J. E. Pettigrew, and H. H. Stein. 2013. Effects of dietary soybean oil on pig growth performance, retention of protein, lipids, and energy, and on the net energy of corn in diets fed to growing or finishing pigs. J. Anim. Sci. 91:3283-3290. DOI ScienceOn
33	Kleiber, M. 1975. The fire of life, 2nd Ed. (Ed. R. E. Krieger), New York, NY.
34	Knap, P. 2000. Variation in maintenance requirements of growing pigs in relation to body composition. A simulation study. Ph. D. Thesis, University of Wageningen, Wageningen, The Netherlands.
35	Koong, L. J., J. A. Nienaber, and H. J. Mersmann. 1983. Effects of plane of nutrition on organ size and fasting heat production in genetically obese and lean pigs. J. Nutr. 113:1626-1631.
36	Le Bellego, L., J. van Milgen, S. Dubois, and J. Noblet. 2001. Energy utilization of low-protein diets in growing pigs. J. Anim. Sci. 79:1259-1271.
37	Le Goff, G. and J. Noblet. 2001. Comparative total tract digestibility of dietary energy and nutrients in growing pigs and adult sows. J. Anim. Sci. 79:2418-2427.
38	Lizardo, R., J. van Milgen, J. Mourot, J. Noblet, and M. Bonneau. 2002. A nutritional model of fatty acid composition in the growing-finishing pig. Livest. Prod. Sci. 75:167-182. DOI ScienceOn
39	Cozannet, P., Y. Primot, C. Gady, J. P. Metayer, M. Lessire, F. Skiba, and J. Noblet. 2010. Energy value of wheat distillers grains with solubles for growing pigs and adult sows. J. Anim. Sci. 88:2382-2392. DOI ScienceOn
40	Close, W. H. 1996. Modelling the growing pig: Predicting nutrient needs and responses. In: Biotechnology in the Feed Industry. The living gut: Bridging the gap between nutrition and performance (Ed. T. P. Lyons and K. A. Jacques). Proc. Alltech's 12th Annual Symposium. Nottingham University Press, Nottingham, UK. pp. 289-297.
41	de Goey, L. W. and R. C. Ewan. 1975. Energy values of corn and oats for young swine. J. Anim. Sci. 40:1052-1057.
42	de Greef, K. H., M. W. A. Verstegen, B. Kemp, and P. L. van der Togt. 1994. The effect of body weight and energy intake on the composition of deposited tissue in pigs. Anim. Prod. 58:263-270.
43	de Lange, C. F. M. 2008. Efficiency of utilization of energy from protein and fiber in the pig- A case for NE systems. In: Proc. Midwest Swine Nutr. Conf., Indianapolis, IN. pp. 58-72.
44	de Lange, C. F. M. and S. H. Birkett. 2005. Characterization of useful energy content in swine and poultry feed ingredients. Can. J. Anim. Sci. 85:269-280. DOI
45	de Lange, C. F. M., J. van Milgen, J. Noblet, S. Dubois, and S. Birkett. 2006. Previous feeding level influences plateau heat production following a 24 h fast in growing pigs. Br. J. Nutr. 95:1082-1087. DOI ScienceOn
46	Emmans, G. C. 1999. Energy flows. In: A Quantitative Biology of the Pig (Ed. I. Kyriazakis). CABI Publishing, Wallingford, U. K. pp. 363-377.
47	Ewan, R. C. 2001. Energy utilization in swine nutrition. In: Swine Nutrition, 2nd Ed. (Ed. A. J. Lewis and L. L. Southern). CRC Press, Washington, DC. pp. 85-94.
48	Black, J. L. and C. F. M. de Lange. 1995. Introduction to the principles of nutrient partitioning for growth. In: Modelling Growth in the Pig (Ed. P. J. Moughan, M. W. A. Verstegen, and M. I. Visser-Reynevel). Wageningen Press, Wageningen, The Netherlands. pp. 115-122.
49	Giles, L. R., M. L. Lorschy, H. J. Bray, and J. L. Black. 1998. Predicting feed intake in growing pigs. In: Progress in Pig Science (Ed. J. Wiseman, M. A. Varley, and J. P. Chadwick). Nottingham University Press, Nottingham, U.K. pp. 209-228.
50	Black, J. L. 2000. Bioavailability: the energy component of a ration for monogastric animals. In: Feed Evaluation: Principle and Practice (Ed. P. J. Moughan, M. W. A. Verstegen, and M. I. Visser-Reyneveld). Wageningen Press, Wageningen, The Netherlands. pp. 133-152.
51	Blaxter, K. L. 1989. Energy metabolism in animals and man. Cambridge University Press, Cambridge, UK.
52	Blok, M. C. 2006. Development of a new net energy formula by CVB, using the database of INRA. Int. Sym. Proc. Net energy systems for growing and fattening pigs. Vejle, Denmark. pp. 40-57.
53	Boisen, S. 2007. New concept for practical feed evaluation systems. DJF Animal Science No. 79. Research Centre Foulum, Denmark.
54	Boisen, S. and M. W. A. Verstegen. 2000. Developments in the measurement of the energy content of feeds and energy utilisation in animals. In: Feed evaluation: principle and practice (Ed. P. J. Moughan, M. W. A. Verstegen, and M. I. Visser-Reyneveld). Wageningen Press, Wageningen, The Netherlands. pp. 57-76.
55	Bray, H. J., L. R. Giles, J. M. Gooden, and J. L. Black. 1997. Energy expenditure in growing pigs infected with pleuropneumonia. In: Energy Metabolism of Farm Animals (Ed. K. J. McCracken, E. F. Unsworth, and A. R. G. Wylie). Proceedings of the 14th Symposium on Energy Metabolism, Newcastle, Northern Ireland. pp. 291-294.
56	Brown, D. 1982. The metabolic body size of the growing pig. Livest. Prod. Sci. 9:389-398. DOI ScienceOn
57	Baldwin, R. L. 1995. Energy requirements for maintenance and production. In: Modeling Ruminant Digestion and Metabolism. (Ed. R. L. Baldwin). Chapman and Hall, London, UK. pp. 148-188.
58	Chwalibog, A. 1991. Energetics of animal production. Acta Agric. Scand. 41:147-160. DOI
59	Ayoade, D. I., E. Kiarie, M. A. Trinidade Neto, and C. M. Nyachoti. 2012. Net energy of diets containing wheat-corn distillers dried grains with solubles as determined by indirect calorimetry, comparative slaughter, and chemical composition methods. J. Anim. Sci. 90:4373-4379. DOI ScienceOn
60	Bakker, G. C. M. 1996. Interaction between carbohydrates and fat in pigs. Ph.D. Thesis, University of Wageningen, Wageningen, The Netherlands.
61	Baldwin, R. L. and A. C. Bywater. 1984. Nutritional energetics of animals. Annu. Rev. Nutr. 4:101-114. DOI ScienceOn
62	Birkett, S. and K. de Lange. 2001. Limitations of conventional models and a conceptual framework for a nutrient flow representation of energy utilization by animals. Br. J. Nutr. 86:647-659. DOI ScienceOn
63	Verstegen, M. W. A. 2001. Developments towards net energy systems in feeds and animals. Western Nutr. Conf., Saskatoon, Canada. pp. 170-184.
64	Black, J. L. 1995. Modelling energy metabolism in the pig - critical evaluation of a simple reference model. In: Modelling Growth in the Pig (Ed. P. J. Moughan, M. W. A. Verstegen, and M. I. Visser-Reyneveld). Wageningen Press, Wageningen, The Netherlands. pp. 87-102.
65	van Milgen, J., J. F. Bernier, Y. Lecozler, S. Dubois, and J. Noblet. 1998. Major determinants of fasting heat production and energetic cost of activity in growing pigs of different body weight and breed/castration combination. Br. J. Nutr. 79:509-517. DOI ScienceOn
66	van Milgen, J. and J. Noblet. 2000. Modelling energy expenditure in pigs. In: Modelling Nutrient Utilization in Farm Animals (Ed. J. P. McNamara, J. France, and D. E. Beever). CAB International, Oxon, U. K. pp. 103-114.
67	van Milgen, J. and J. Noblet. 2003. Partitioning of energy intake to heat, protein, and fat in growing pigs. 81(E. Suppl. 2):E86-E93.
68	van Milgen, J., A. Valancogne, S. Dubois, J. Y. Dourmad, B. Seve, and J. Noblet. 2008. InraPorc: A model and decision support tool for the nutrition of growing pigs. Anim. Feed Sci. Technol. 143:387-405. DOI ScienceOn
69	Whittemore, C. T., M. J. Hazzledine, and W. H. Close. 2003. Nutrient requirement standards for pigs. British Society of Animal Science. Penicuik.
70	Whittemore, C. T. 1997. An analysis of methods for the utilisation of net energy concepts to improve the accuracy of feed evaluation in diets for pigs. Anim. Feed Sci. Technol. 68:89-99. DOI ScienceOn
71	Wu, Z., D. Li, Y. Ma, Y. Yu, and J. Noblet. 2007. Evaluation of energy systems in determining the energy cost of gain of growing-finishing pigs fed diets containing different levels of dietary fat. Arch. Anim. Nutr. 61:1-9. DOI ScienceOn
72	Rijnen, M. M. J. A., J. Doorenbos, J. J. Mallo, and L. A. den Hartog. 2004. The application of the net energy system for swine. In: Proc. Western Nutr. Conf., Saskatoon, Canada. pp. 151-168.
73	Robles, A. and R. C. Ewan. 1982. Utilization of energy of rice and rice bran by young pigs. J. Anim. Sci. 55:572-577.
74	Sauvant, D., J. M. Perez, and G. Tran. 2004. Tables of composition and nutritional value of feed materials: Pig, poultry, sheep, goats, rabbits, horses, and fish. Wageningen Academic Publishers, Wageningen, the Netherlands and INRA ed. Paris, France.
75	Schiemann, R., K. Nehring, L. Hoffmann, W. Jentsch, and A. Chudy. 1972. Energetische Futterbevertung und Energienormen. VEB Deutscher Landwirtschaftsverlag, Berlin.

Reference

7	C. Kong. (2014) Asian-Australasian Journal of Animal Sciences Evaluation of Amino Acid and Energy Utilization in Feedstuff for Swine and Poultry Diets / 27 (7) , 917
2	Se Won Park. (2014) Korean Journal for Food Science of Animal Resources Effect of Dietary Supplementation of Blood Meal and Additional Magnesium on Carnosine and Anserine Concentrations of Pig Muscles / 34 (2) , 252
4	Chan S. Park. (2014) Animal Science Journal Digestible and metabolizable energy in corn grains from different origins for growing pigs / 86 (4) , 415
11	Gang Il Lee. (2015) Asian-Australasian Journal of Animal Sciences Growth Performance of Early Finishing Gilts as Affected by Different Net Energy Concentrations in Diets / 28 (11) , 1614
7	W. B. Kwon. (2015) Asian-Australasian Journal of Animal Sciences Effects of Supplemental Beta-mannanase on Digestible Energy and Metabolizable Energy Contents of Copra Expellers and Palm Kernel Expellers Fed to Pigs / 28 (7) , 1014
11	S. Vigors. (2016) animal Pigs that are divergent in feed efficiency, differ in intestinal enzyme and nutrient transporter gene expression, nutrient digestibility and microbial activity / 10 (11) , 1848
12	S. A. Lee. (2016) Asian-Australasian Journal of Animal Sciences Different Coefficients and Exponents for Metabolic Body Weight in a Model to Estimate Individual Feed Intake for Growing-finishing Pigs / 29 (12) , 1756
9	(2017) Asian-Australasian Journal of Animal Sciences Effect of dietary net energy concentrations on growth performance and net energy intake of growing gilts / 30 (9) , 1314
11	(2017) Animal Production Science Procedures for determining digestibility of amino acids, lipids, starch, fibre, phosphorus, and calcium in feed ingredients fed to pigs / 57 (11) , 2317
6	(2017) Journal of Animal Science Net energy of hemp hulls and processed hemp hull products fed to growing pigs and the comparison of net energy determined via indirect calorimetry and calculated from prediction equations1 / 95 (6) , 2649
0	(2018) Revista Brasileira de Zootecnia Dietary net energy plans for barrows from 25 to 100 kg body weight / 47 (0)
0	(2018) Revista Brasileira de Zootecnia Dietary net energy for gilts from 25 to 100 kg body weight / 47 (0)
1	(2018) Journal of Animal Science and Biotechnology Methodologies on estimating the energy requirements for maintenance and determining the net energy contents of feed ingredients in swine: a review of recent work / 9 (1)
11	(2013) International journal of poultry science Mixing Performance of a Novel Flat-Bottom Vertical Feed Mixer / 14 (11) , 625
6	(2017) Ciência e Agrotecnologia Predicting the metabolizable energy of first and second corn harvests for piglets / 41 (6) , 683
1	(2018) Asian-Australasian Journal of Animal Sciences Effects of inclusion level and adaptation period on nutrient digestibility and digestible energy of wheat bran in growing-finishing pigs / 31 (1) , 116
4	(2018) Animal Production Science Predicting the nutritional quality of feed ingredients for pigs using near-infrared spectroscopy (NIRS) and chemical analysis / 58 (4) , 709
4	(2018) Asian-Australasian Journal of Animal Sciences Effects of dietary β-mannanase supplementation on the additivity of true metabolizable energy values for broiler diets / 31 (4) , 564
1	(2014) Journal of Animal Science and Biotechnology Metabolizable energy, nitrogen balance, and ileal digestibility of amino acids in quality protein maize for pigs / 5 (1)
13443941	(2019) Animal Science Journal Effect of different time intervals after feeding on plasma metabolites in growing pigs: an UPLC-MS-based metabolomics study / (13443941)
8	(2013) Food additives & contaminants. Part A. Chemistry, analysis, control, exposure & risk assessment New feed ingredients: the insect opportunity / 34 (8) , 1384
5	(2013) Journal of animal science Prediction of digestible and metabolizable energy of corn distillers dried grains with solubles for growing pigs using in vitro digestible nutrients / 96 (5) , 1818
10	(2013) PLoS ONE Effect of dietary fiber content on nutrient digestibility and fecal microbiota composition in growing-finishing pigs / 13 (10) , e0206159
2	(2013) Translational animal science Energy, amino acid, and phosphorus digestibility and energy prediction of thermally processed food waste sources for swine / 3 (2) , 676
2	(2013) The Journal of applied poultry research A Review of Dietary Metabolizable and Net Energy: Uncoupling Heat Production and Retained Energy / 28 (2) , 231
9	(2013) Physiological genomics Analysis of the basal colonic innate immune response of pigs divergent in feed efficiency and following an ex vivo lipopolysaccharide challenge / 51 (9) , 443
9	(2019) Asian-Australasian journal of animal sciences Metabolizable energy requirement for maintenance estimated by regression analysis of body weight gain or metabolizable energy intake in growing pigs / 32 (9) , 1397
9	(2013) Asian-Australasian journal of animal sciences Effect of different sources and inclusion levels of dietary fat on productive performance and egg quality in laying hens raised under hot environmental conditions / 32 (9) , 1407
1	(2013) Animals Effects of a Hatchery Byproduct Mixture on Growth Performance and Digestible Energy of Various Hatchery Byproduct Mixtures in Nursery Pigs / 10 (1) , 174
6	(2013) Animals Increasing Dietary Lysine Impacts Differently Growth Performance of Growing Pigs Sorted by Body Weight / 10 (6) , 1032
2	(2013) Korean journal of agricultural science Growth performance and nutrient digestibility of grower and finisher pigs fed diets containing non-genetically modified soybean meal / 47 (2) , 229
2	(2013) Korean journal of agricultural science Growth performance and nutrient digestibility of growing-finishing pigs under different energy concentrations / 47 (2) , 275
2	(2021) Animal bioscience Prediction equations for digestible and metabolizable energy concentrations in feed ingredients and diets for pigs based on chemical composition / 34 (2) , 306
1	(2013) Acta agriculturæ Scandinavica. Section A, Animal science The effect of inclusion of fibre-rich by-products on the performance of growing and finishing pigs (pilot study) / 70 (1) , 23
1	(2013) Animal nutrition Protein and energy concentrations of meat meal and meat and bone meal fed to pigs based on in vitro assays / 7 (1) , 252
2	(2021) Translational animal science Effects of feeding corn distillers dried grains with solubles diets without or with supplemental enzymes on growth performance of pigs: a meta-analysis / 5 (2) , txab029
5	(2021) Animals Measures Matter-Determining the True Nutri-Physiological Value of Feed Ingredients for Swine / 11 (5) , 1259
None	(2021) Livestock science Macauba (Acrocomia aculeata) pulp meal as alternative raw material for growing-pigs / 252 (None) , 104675
10	(2013) Animal bioscience A regression for estimating metabolizable glucose in diets of weaned piglets for optimal growth performance / 34 (10) , 1643

1	Effect of Dietary Supplementation of Blood Meal and Additional Magnesium on Carnosine and Anserine Concentrations of Pig Muscles / [Park, Se Won;Kim, Chan Ho;Kim, Jong Woong;Shin, Hye Seong;Paik, In Kee;Kil, Dong Yong;] / Food Science of Animal Resources
2	Evaluation of Amino Acid and Energy Utilization in Feedstuff for Swine and Poultry Diets / [Kong, C.;Adeola, O.;] / Asian-Australasian Journal of Animal Sciences