Prediction of net energy value of feeds for growing pigs.

Digestible (DE), metabolizable (ME), and net (NE) energy values of 61 diets were measured in 45-kg growing Large White boars. Net energy was calculated as energy retained at an average ME intake equivalent to 540 kcal/kg BW.60 plus fasting heat production estimated from data of the present experiment as 179 kcal/kg BW.60. Retained energy was measured as the difference between ME intake and heat production obtained in respiration chambers. The amounts of DE digested before the end of the ileum (DEi) and in the hindgut (DEh) were also measured for each diet. Regression equations for predicting dietary NE content from digestible nutrient levels or from DE or ME and chemical characteristics or from chemical composition only were calculated. Efficiencies of utilization of ME for NE (k, %) were also obtained. The mean k value for the 61 diets was 74% (range: 69 to 77). Digestible nutrients were used differently for NE: k values varied from approximately 60% for digestible CP or digestible cell wall fractions to 82% for starch and 90% for digestible ether extract. Accordingly, k for ME associated with DEh was lower than ME from DEi (58 vs 76%). Equations for predicting NE content are proposed. Their applicability, the comparison with other available NE prediction equations, and the effects of energy system on diet formulation are discussed.

[1]  J. Noblet,et al.  Effect of protein and lysine levels in the diet on body gain composition and energy utilization in growing pigs. , 1987, Journal of animal science.

[2]  J. Dourmad,et al.  Energy utilization in pregnant and lactating sows: modeling of energy requirements. , 1990, Journal of animal science.

[3]  M. Kirchgessner,et al.  Energetische Verwertung von intracaecal infundierter Essig‐ und Propionsäure bei Sauen , 1988 .

[4]  J. Noblet,et al.  Comparative digestibility of energy and nutrients in growing pigs fed ad libitum and adults sows fed at maintenance , 1993 .

[5]  J. Noblet,et al.  Prediction of digestibility of nutrients and energy values of pig diets from chemical analysis. , 1993, Journal of animal science.

[6]  S. Imoto,et al.  VFA production in the pig large intestine. , 1978, Journal of animal science.

[7]  J. Brillouet,et al.  Determination of water-insoluble cell walls in feeds: interlaboratory study. , 1989, Journal - Association of Official Analytical Chemists.

[8]  J. Noblet,et al.  Digestible, metabolizable and net energy values of 13 feedstuffs for growing pigs: effect of energy system , 1993 .

[9]  G. van Kempen,et al.  The net energy content of pig feeds according to the rostock formula the value of starch in the feed. , 2009, Zeitschrift fur Tierphysiologie, Tierernahrung und Futtermittelkunde.

[10]  H. Jørgensen,et al.  THE NET ENERGY VALUE OF DIETS FOR GROWTH IN PIGS IN RELATION TO THE FERMENTATIVE PROCESSES IN THE DIGESTIVE TRACT AND THE SITE OF ABSORPTION OF THE NUTRIENTS , 1983 .

[11]  J. Noblet,et al.  Metabolic utilization of dietary energy and nutrients for maintenance energy requirements in sows: basis for a net energy system , 1993, British Journal of Nutrition.

[12]  J. Noblet,et al.  Contribution of the hindgut to digestion of diets in growing pigs and adult sows: effect of diet composition , 1993 .

[13]  A. Just The net energy value of balanced diets for growing pigs , 1982 .

[14]  R. C. Ewan Predicting the energy utilization of diets and feed ingredients by pigs , 1989 .

[15]  J. Noblet,et al.  Energy cost of standing activity in sows , 1993 .

[16]  E. Annison Feeding standards for Australian livestock. Pigs. , 1987 .