Objective: The net energy requirement for the maintenance (NEm) of broilers was determined using regression models by the indirect calorimetry method (ICM) or the comparative slaughter method (CSM).
Methods: A 2×4 factorial arrangement of treatments including the evaluation method (ICM or CSM) and feed intake (25%, 50%, 75%, or 100% of ad libitum recommended) was employed in this experiment. In the ICM, 96 male Arbor Acres (AA) birds aged d 15 were used with 4 birds per replicate and 6 replicates in each treatment. In the CSM, 116 male AA birds aged d 15 were used. Among these 116 birds, 20 were selected as for initial data and 96 were assigned to 4 treatments with 6 replicate cages and 4 birds each. The linear regression between retained energy (RE) and metabolizable energy intake (MEI) or the logarithmic regression between heat production (HP) and MEI were used to calculate the metabolizable or net energy requirement for maintenance (MEm) or NEm, respectively.
Results: The evaluation method did not detect any differences in the metabolizable energy (ME), net energy (NE), and NE:ME of diet, and in the MEI, HP, and RE of broilers. The MEI, HP, and RE of broilers decreased (p<0.01) as the feed intake decreased. No evaluation method× feed intake interaction was observed on these parameters. The MEm and NEm estimated from the linear relationship were 594 and 386 kJ/kg of body weight (BW)0.75/d in the ICM, and 618 and 404 kJ/kg of BW0.75/d in the CSM, respectively. The MEm and NEm estimated by logarithmic regression were 607 and 448 kJ/kg of BW0.75/d in the ICM, and were 619 and 462 kJ/kg of BW0.75/d in the CSM, respectively.
Conclusion: The NEm values obtained in this study provide references for estimating the NE values of broiler diets.

1 Noblet J, "Utilisation of metabolisable energy of feeds in pigs and poultry: interest of net energy systems?" 26-35, 2010

2 O'Neill SJB, "The heat production of hens and cockerels maintained for an extended period of time at a constant environmental temperature of 23°C" 82 : 549-552, 1974

3 Close WH, "The effects of plane of nutrition and environmental temperature on the energy metabolism of the growing pig. 2. Growth rate, including protein and fat deposition" 40 : 423-431, 1978

4 D. Ning, "The Net Energy Values of Corn, Dried Distillers Grains with Solubles and Wheat Bran for Laying Hens Using Indirect Calorimetry Method" 아세아·태평양축산학회 27 (27): 209-216, 2014

5 Noblet J, "Recent developments in net energy research for swine" 18 : 149-156, 2007

6 De Lange K, "Previous feeding level influences plateau heat production following a 24 h fast in growing pigs" 95 : 1082-1087, 2006

7 Noblet J, "Prediction of net energy value of feeds for growing pigs" 72 : 344-354, 1994

8 Van Milgen J, "Partitioning of energy intake to heat, protein, and fat in growing pigs" 81 (81): E86-E93, 2003

9 Carré B, "Partition of metabolizable energy, and prediction of growth performance and lipid deposition in broiler chickens" 94 : 1287-1297, 2015

10 Larbier M, "Nutrition and Feeding of Poultry" Nottingham University Press 47-73, 1992

11 Sakomura NK, "Modeling metabolizable energy utilization in broiler breeder pullets" 82 : 419-427, 2003

12 Sakomura NK, "Modeling energy utilization and growth parameter description for broiler chickens" 84 : 1363-1369, 2005

13 Sakomura NK, "Model for metabolizable energy requirements of laying hens" 34 : 575-583, 2005

14 Labussière E, "Maintenance energy requirements of growing pigs and calves are influenced by feeding level" 141 : 1855-1861, 2011

15 MacLeod MG, "Heat production by the mature male turkey (Meleagris gallopavo): Preliminary measurements in an automated, indirect, open-circuit multi-calorimeter system" 26 : 325-333, 1985

16 Noblet J, "Fasting heat production and metabolic BW in group-housed broilers" 9 : 1138-1144, 2015

17 Farrel DJ, "Energy requirements of poultry" British Poultry Science 1-23, 1974

18 Brouwer E, "Energy metabolism" Academic Press 441-443, 1965

19 Chizzotti ML, "Energy and protein requirements for growth and maintenance of F1 Nellore×Red Angus bulls, steers, and heifers" 85 : 1971-1981, 2007

20 Balnave D, "Energy Requirements of Poultry" British Poultry Science Ltd 25-46, 1974

21 Yang Y, "Effects of mannanoligosaccharide in broiler chicken diets on growth performance, energy utilisation, nutrient digestibility and intestinal microflora" 49 : 186-194, 2008

22 Liu W, "Effects of body weight on total heat production and fasting heat production in net energy evaluation of broilers" 26 : 2118-2125, 2014

23 Barekatain MR, "Effect of sorghum distillers dried grains with solubles and microbial enzymes on metabolizable and net energy values of broiler diets" 93 : 2793-2801, 2014

24 Quiniou N, "Effect of energy intake on performance, nutrient and tissue gain and protein and energy utilization in growing boars" 61 : 133-143, 1995

25 Nieto R, "Effect of dietary protein quality on energy metabolism in growing chickens" 74 : 163-172, 1995

26 Swatson HK, "Effect of dietary protein level, amino acid balance and feeding level on growth, gastrointestinal tract, and mucosal structure of the small intestine in broiler chickens" 51 : 501-515, 2002

27 Van Milgen J, "Dynamic aspects of oxygen consumption and carbon dioxide production in swine" 78 : 397-410, 1997

28 Hill FW, "Comparison of metabolizable energy and productive energy determinations with growing chicks" 64 : 587-603, 1958

29 Lofgreen GP, "A system for expressing net energy requirements and feed values for growing and finishing beef cattle" 27 : 793-806, 1968