2. With young broilers the AME and AMEN values of a sample of grass meal were estimated to be 5.97 ± 0.45 and 6.05 + 0.46 MJ/kg dry matter respectively.
3. With adult laying hens the AME and AMEN values of the sample of grass meal were estimated to be 5.36 ± 1.04 and 6.26 ± 0.96 MJ/kg dry matter respectively and the corresponding true metabolisable energy (TME) and nitrogen‐corrected TME (TMEN) values were shown to be 9.12 ± 1.25 and 8.66 ± 1.33 MJ/kg dry matter.
4. It was further illustrated that if the dietary intake of the adult birds had been 100 g/d, the AME value of the grass meal would have been estimated as 8.33 MJ/kg dry matter. 相似文献
2. The low AME was due to a reduced starch digestibility and was not improved by grinding the wheat finely or by steam pelleting the diet.
3. Higher AME values were obtained when determinations were made with adult cockerels than with growing broilers when the conventional technique was used.
4. AME values determined using a rapid bioassay technique (Farrell, 1978) with growing broilers or adult cockerels were considerably higher than values determined using the conventional procedure with growing broilers.
5. Inter‐laboratory studies showed that the true metabolisable energy (TME) assay gave reproducible values for individual and blended wheat samples, but that these values were higher than AME values determined by the conventional procedure. Similar TME values were found with growing broilers and adult cockerels. 相似文献
2. The average values of nitrogen lost, endogenous energy losses (EEL) and endogenous energy losses corrected to zero‐nitrogen balance (EELn) were found to be 1.18 g, 62.13 kJ and 21.51 kJ/bird/48h, respectively, from adult cockerels given an energy supply as 50 g glucose during starvation.
3. The nitrogen‐corrected apparent metabolisable energy (AMEn) values for feed‐grade lentil, lentil bran and wild vetch seed, respectively, were 6.84, 3.05 and 14.31 kJ/g dry matter. The nitrogen‐corrected true metabolisable energy (TMEn) values for the respective feedingstuffs were 7.44, 3.65 and 14.90 kJ/g dry matter. 相似文献
2. In younger birds, endogenous energy losses were higher when measured in starved birds than when estimated by regression analysis.
3. In young birds, feeding rate had no effect on AME of diets containing 50 g lipids/kg but it significantly affected TME. These results were reversed in adults. AME and TME values of diets containing 150 g lipids/kg were affected by the feeding rate in both young and adult birds.
4. Bile salts increased metabolisable energy values of diets containing high concentrations of saturated fatty acids and their effect was more pronounced in young birds. 相似文献
2. Food intake was measured daily for 21 d. Body composition was determined at 42 d and gains in body mass, protein, fat and gross energy calculated by comparison with a group analysed at 21 d. Heat production was calculated by difference between AME intake and energy gain.
3. Decrease of food mass intake with increased dietary AME concentration limited the increase in AME intake to about 25%, despite the near 2‐fold range of AME concentrations.
4. There was no effect of CP concentration on food mass intake. CP intake was directly related to CP: AME ratio.
5. When body weight differences were taken into account, heat production was independent of dietary AME concentration, but increased by about 8% on the higher‐protein diets.
6. There were strong linear correlations between dietary CP:AME ratio and carcase protein: energy ratio, carcase fat content and carcase protein content.
7. It was concluded that the growing fowl responded to dietary nutrient: energy ratio, and the associated differences in nutrient and energy intakes, by varying the rate of energy deposition as fat, without regulatory variation of energy dissipation as heat. 相似文献
The TME value found at the cool temperature (5 to 15 °C) was significantly higher than those found at hot (25 to 35 °G) and control (22 °C) temperatures. AME values were not significantly affected. 相似文献
2. Body‐weight gain and carcass fat and water content increased and fertility decreased with increasing energy allowance. Maximum egg production occurred at an energy intake of 1.73 MJ AME/bird d.
3. Differences in egg weight and hatchability were related to differences in both energy and protein intake. The highest egg weight occurred at the highest allowance of energy and protein. Hatchability was depressed where the daily allowances of protein and energy were in a ratio of more than 15 g protein: 1 MJ AME.
4. Apart from egg size no significant effects on reproductive performance were observed when dietary protein intake was varied from 27 to 19.5 g/bird d.
5. Requirements of broiler breeder hens for protein during lay may be lower than previously thought. For the strain used a protein intake of 19.5 g/bird d appeared adequate provided essential amino acid concentrations were maintained.
6. The close relationships between body weight and energy allowance and the latter and egg production make body‐weight gain a useful guide to management. A body‐weight gain of about 1.1 kg from 21 to 36 weeks of age was associated with optimum performance in this study. 相似文献
2. In a separate study the endogenous energy losses (EEL) of adult Rhode Island Red (RIR) and adult broiler roosters were measured when given a supply of energy.
3. AME value for RSM tended to be lower for cockerels than for hens, whereas the opposite was noted for SBM and WFP.
4. This study showed that AME of ingredients could be influenced by choice of technique. These differences are accentuated for some ingredients, such as SBM and RSM, although there was no difference in ranking ingredients tested within the AME and TME systems.
5. Assuming that birds are receiving an energy source, the EEL0 per kg metabolic body weight (W0.75) did not differ between adult broiler cockerels and adult Rhode Island Red cockerels.
6. The AME0 values with laying hens for winter HG‐RSM, summer HG‐RSM, LG‐RSM, SBM and WFP were 7.0, 7.6, 8.7, 11.5 and 11.3 kJ/g dry matter. TME0 values with cockerels for the respective ingredients were 8.4, 8.5, 9.5, 12.6 and 13.4 kJ/g dry matter. 相似文献
2. A water‐insoluble pentosan preparation (WIP, 720 g arabinoxy‐lan/kg) caused a depression of apparent metabolisable energy (AME) of 1.63 MJ/kg DM at the highest level of inclusion (41.9 g/kg). Broilers maintained on this diet showed significant growth depression and a decrease in feed conversion efficiency.
3. A water‐soluble pentosan preparation (WSP, 520 g arabinoxy‐lan/kg) showed less anti‐nutritive activity.
4. In a second experiment the AME of rice (pearled), maize, sorghum, wheat, triticale, barley and rye was determined. The AME values obtained were highly correlated (r= — 0.98, P<0.001) with the summed levels of pentosans and β‐glucans found in the cereals.
5. It was concluded that the pentosans of wheat possess anti‐nutritive activity when present in broiler diets and that similar polysaccharides may influence the nutritive value of other cereals. 相似文献
2. The decrease in hatchability that occurred on the high protein (27.0 g CP), low energy (1.52 MJ AME) allowance from 26 to 36 weeks of age was due to an increase in the percentage of dead embryos in the second week of incubation and an increase in the number of “pipped” eggs at the end of incubation.
3. The low hatchability of eggs from birds on the 1.88 MJ AME allowance from 37 to 64 weeks could be related to the incidence of deaths in the first 5 d of the incubation period.
4. Malformations and malpositions of the embryo were not affected by maternal energy or protein allowance. 相似文献
2. Ten dietary treatments were offered to 6 replicate cages (6 birds per cage) of male Ross 308 chickens from 7 to 28 d post-hatch. The effects of treatment on relative gizzard weights, gizzard contents, pancreatic weights and pH of gizzard digesta were monitored. Parameters of growth performance, nutrient utilisation (apparent metabolisable energy [AME], metabolisable to gross energy [ME:GE] ratios, nitrogen [N] retention and N-corrected AME [AMEn]), apparent starch and protein (N) digestibility coefficients and disappearance rates in for small intestinal segments and concentrations of free amino acids in plasma taken from the anterior mesenteric vein were determined.
3. Whole grain feeding (WGF) did not influence weight gain, but 30% post-pellet blended and 15 and 30% post-pellet separated treatments significantly depressed (P < 0.05) feed intakes while the 30% post-pellet separated treatment improved (P < 0.01) feed conversion ratios (FCR). WGF regimes significantly increased relative gizzard weights.
4. Overall, WGF generated profound responses in AME, ME:GE ratios, N retention and AMEn that were highly correlated with relative gizzard weights. In general, WGF improved starch and protein (N) digestibilities and again there were some correlations with these outcomes and relative gizzard weights.
5. Post-pellet WG inclusions where WG and pelleted concentrate were offered separately provided chickens with the opportunity to choice feed. Birds showed a preference for the relatively high-protein pelleted concentrate and at 30% WG, this resulted in an improvement in FCR of 7.69% (1.260 versus 1.365; P < 0.001) relative to the ground-grain control diet. 相似文献
2. In only one experiment was weight gain significantly improved when the barley was heated.
3. Autoclaving barley at 120 °C for 30 min reduced dietary dry matter digestibility and treating the barley with dilute acid before heating had no effect on its nutritive value.
4. Supplementing diets containing commercial barley with a‐amylase produced slightly conflicting results in that there was an improved weight gain, food conversion efficiency and digestibility value in two of three experiments.
5. The digestibility and metabolisable energy values of a North American six‐row spring barley (Glacier) were significantly improved by enzyme supplementation.
6. The effect of the enzyme on diets containing a high amylose barley (Glacier Pentlandfield) was positive but not significant. 相似文献
2. In Experiment 1, the apparent metabolisable energy (AME) and the apparent ileal amino acid digestibility of the three cultivars were determined. The cultivar effects were not significant for AME and apparent ileal amino acid digestibility coefficients. In general, amino acids in narrow-leafed lupin were well digested, with the notable exception of methionine. Among the indispensable amino acids, arginine had the highest digestibility coefficient (0·92–0·95), while the lowest was for methionine (0·74–0·83).
3. In Experiment 2, using the energy and digestible amino acid values determined in Experiment 1, diets containing 200?g/kg of the three lupin cultivars were formulated and the effects of feeding these diets on the performance and the digestive tract development of broiler starters were investigated.
4. Weight gain, feed intake and feed per gain of broilers fed narrow-leafed lupins diets were similar to those fed on the maize-soy basal diet. The performance of birds fed on diets containing different cultivars of lupins was also similar. Birds fed on lupin diets had similar excreta scores to those fed on the basal diet.
5. Inclusion of 200?g/kg lupins in broiler diets had no effects on the relative weight and length of the intestinal tract. Broilers fed on lupin diets, however, had higher relative weights of liver.
6. These results suggest that narrow-leafed lupins are good sources of protein, but poor sources of AME and sulphur-containing amino acids. It is concluded that, when diets are properly balanced in terms of AME and digestible amino acids, lupins can be included at 200?g/kg inclusion level in broiler starter diets with no adverse effects on performance. 相似文献
2.?Enzyme products with xylanase activity were added to a basal diet to provide 4 dietary treatments comprising control (no enzyme), Avizyme 1300 (1 kg/tonne), Kemzyme W1 (1 kg/tonne), and Bio-Feed Wheat CT (200 g/tonne). The basal diet comprised (in g/kg), 800 wheat, 155 casein, 20 dicalcium phosphate, 11 limestone, 7 D,L-methionine, 2 vitamin and mineral premix, 3 sodium chloride and 2 choline chloride (60%).
3.?AME values for diets were determined in a 7-d energy balance study commencing when chickens were 21 d of age. WTTT was the time elapsed (in min), from time of administration by oral gavage of 200 mg ferric oxide in a gelatine capsule, to time of first observation of the distinctive red colouration in droppings.
4.?The mean AME value for the wheat was high (15·7 MJ/kg dry matter) and ranged from 14·4 to 16·3 MJ/kg dry matter for individual birds. Mean WTTT was 206 min and ranged from 105 to 429 min. AME and WTTT were unaffected by enzyme addition to the diet, and the interaction between diet and gender was not significant.
5.?There was a significant but weak positive relationship between AME and whole tract transit time, with AME increasing by 2·2 kJ/min. This relationship was unaffected by gender of the chicken. 相似文献
The more severely confined birds had depressed plasma alkaline phosphatase activity but a raised plasma cholesterol level after 35 d. The alkaline phosphatase activity returned to normal after 70 d but the hypercholesterolaemia persisted. Acid phosphatase activity and plasma protein levels were unaffected by the treatments.
Pullets in the smaller cages laid fewer eggs but egg weight was unaffected.
Neither percentage metabolisable energy nor metabolisable nitrogen of the diet was affected by the severity of confinement, though less dietary nitrogen was retained by either group in the first half of the confinement period.
Severe confinement resulted in higher values of percentage metabolisable calcium and phosphorus by the 35th d but these decreased by the 70th d. In the less severely confined birds these values by the 70th d were higher than those at the 35th d. 相似文献
2. No significant interactions occurred, so only the main effects were discussed. At 7–14?d, feed conversion ratio (FCR) showed a significant linear response with increased glycerol inclusion. However quadratic responses on FCR were observed for the 21–28?d period and 7–28?d.
3. Glycerol digestibility was significantly greater with birds offered the 67?g/kg and 100?g/kg glycerol-based diets in contrast to the digestibility of 33?g/kg glycerol-based diets.
4. Glycerol inclusion level also had an effect on AME, which increased linearly with increasing glycerol inclusion. Birds offered the diets containing glycerol also required less energy per unit gain in contrast to birds offered the control diet.
5. When examining the effect of source of glycerol, source A glycerol resulted in the highest AME (15·20 vs. 14·72?MJ/kg). There was no significant effect of glycerol source on the other performance parameters.
6. Glycerol digestibility was significantly greater with glycerol from source B (John Thompson and Sons, Ltd) with a mean value of 0·848 in contrast to source A (PRS Environmental), which had a somewhat lower mean glycerol digestibility of 0·757.
7. In conclusion, glycerol source did not affect performance and increasing level of glycerol improved FCR, with 67?g/kg inclusion resulting in the most efficient conversion of feed to gain without any negative effects upon nutrient digestibility. 相似文献
2. When 25 g sand/kg was substituted for the components of a basal diet, growth was not affected and the TME value of the diet was apparently higher than that of the basal diet, but not significantly so.
3. The substitution of 50 g filler/kg (25 g sand plus 25 g grit/kg) resulted in a higher TME value than the substitution of either 25 g sand/kg or 25 g grit/kg, significantly so in the latter case.
4. Substituting 25 g cellulose/kg resulted in a decrease in TME value, but not significantly so. 相似文献
2. The different varieties of wheat investigated contained different proportions of water‐soluble to water‐insoluble hemicelluloses.
3. By comparison of the arabinose to xylose ratios it was concluded that water‐soluble and insoluble arabinoxylans of wheat were branched to the same degree.
4. Starch from six wheat varieties grown in the U.K. was very well digested by adult cockerels and true metabolisable energy values of the wheats were high.
5. Small amounts of cell wall carbohydrates were digested by adult cockerels. 相似文献
2. The enzymes were added at 0, 025, 0.50, 0.75 and 1.00 g/kg in diets containing (g/kg) lupins 300, sorghum 543, casein 91, celite (as marker) 20, and vitamins and minerals 46. Control diets, with and without enzyme supplementation contained sorghum and casein at 800 and 134 g/kg, respectively, and no lupins.
3. Growth rates and food conversion ratios (FCR) of birds over 7 days were not affected by lupin inclusion or enzyme supplementation. FCR of broilers fed on the sorghum diet was improved by enzyme A but not by enzyme B.
4. Heal starch digestibilities were slightly lower in birds fed on the lupin control diet (no enzyme) compared to the basal control diet.
5. Enzyme A increased the AME of the lupins from 10.01 MJ/kg DM to 11.65 MJ/kg DM when added at 0.5 g/kg. Higher rates of supplementation did not lead to further increases in AME values.
6. Enzyme A did not improve starch digestion in the diets but insoluble non‐starch polysaccharides concentration in the digesta decreased (50–41–42–71 g/g acid insoluble ash marker) with increasing enzyme supplementation, suggesting that the improvement in AME was the result of increased fermentation of fibre in the hindgut.
7. Enzyme B did not affect the AME of lupins nor the ileal digestibility of nutrients, but caused an increase in the concentrations of soluble non‐starch polysaccharides in the ileal digesta of chickens (19.21.35.77 mg/ml). This was accompanied by an increase in ileal digesta viscosity (11.4.34.2 m.Pa/s). 相似文献
2. There was no significant difference in the apparent metabolisable energy (AME) content amongst the three varieties of maize.
3. Lysine and threonine digestibilities were significantly higher in QPM compared to either HMN or NM. No difference in the digestibilities of other amino acids occurred among the three different maize varieties.
4. There was no difference between diets containing NM or HMN for body weight gain (21 and 40?d of age) and overall feed conversion ratio (0–40?d), but values were significantly higher for QPM (and Lys-supplemented NM) diets. The relative weights of dressed meat yield and giblets were unaffected by dietary replacement of NM with QPM, HMN, or Lys supplementation of the NM diet. However, abdominal fat content decreased and breast meat yield increased with both dietary replacement of NM with QPM and Lys supplementation of the NM diet.
5. The concentration of protein in serum was significantly increased by dietary replacement of NM with QPM. Adding Lys to the NM based diet significantly increased the Ca concentration in serum compared with NM or HMN diets. However, the highest concentration of Ca in serum was found in the QPM diet. The concentration of total cholesterol in serum significantly decreased by either replacing NM with QPM or adding Lys to the NM based diet, compared with the NM diet.
6. These results suggested that the feeding value of quality protein maize was superior to normal maize, while the feeding value of hybrid maize Nityashree was similar to that of normal maize. 相似文献