RU2148937C1 - Method for determining metabolizable energy of feeds for farm poultry - Google Patents

Abstract

FIELD: poultry farming. SUBSTANCE: method involves providing individual keeping of cocks of the same age and equal live weight; holding them for 24-32 hours without access to feed before control feeding; performing control feeding for 17-18 hours or 23-24 hours, during which birds are allowed free feed consumption; gathering dung released by each group of birds during 48 hours from the beginning of feeding process; drying dung and feed samples to constant weight; determining values of gross energy of dried samples and calculating metabolizable energy of feed; determining average ratio of weights of dry matter released with dung and dry matter consumed with feed for each group of birds; comparing obtained ratios in two groups; in case these ratios are equal, using averaged data on consumed feed and released dung for calculating metabolizable energy of feed; in case obtained ratios are not equal, using only data belonging to group with shorter feeding period. Method allows one bird to be continuously used for testing different feeds without necessity for recovery period and preliminary training, with digestibility rate of different products being taken into account. EFFECT: simplified method and increased precision of data obtained. 2 cl, 3 tbl, 2 ex

Description

 The invention relates to the feeding of poultry and is intended for the study of new feed products.

 Currently, domestic poultry has undergone a transition from corn-soy-based diets to cheaper wheat-barley-based feed mixtures. Poultry diets include more and more unconventional and new feed products, products of microbiological synthesis, as well as waste products that have feed value. In this regard, and also due to the continuous increase in feed prices, the evaluation of biological indicators of feed, such as their digestibility and the content of metabolic energy in them, is of great importance.

 The value of the exchange energy of compound feeds can vary significantly depending on the type of ingredients included in them, their quantity and quality. Therefore, along with the accuracy of the estimates, their speed and labor intensity decrease become significant factors.

To determine the exchange energy of feed, there are various methods based on physiological (balance) experiments, the essence of which is the quantitative determination of the feed consumed by the bird and the litter isolated at the same time over a certain period of time. There is a method of determining the exchange energy of feed for poultry, according to which the bird is pre-fed with the test feed for 3-7 days to adapt it to new conditions and release the intestinal tract from the previous feed, followed by an accounting period (3-5 days), with careful consideration of the feed consumed by the bird and its litter. Throughout the experiment, the bird receives plenty of food. Samples of feed and litter are dried at 60-70 ^o C to constant weight, ground, sieved through a sieve, pressed from them weights of 0.6-0.8 g, which are burned in a calorimeter to determine the gross energy and the difference between the gross energy of the feed and litter calculate the metabolic energy of the feed. Determination of metabolic energy in new feed products. Guidelines VNITIP, Zagorsk, 1985, 16 pp. The known method is highly accurate in determining the energy nutritional value of feed. However, its considerable duration and the impossibility of quick estimates of the energy value of feed, as well as the high labor costs, a significant amount of feed necessary for testing, hinder its widespread use.

 A fast method for determining the metabolic energy of feed Farrell D.J. (THE RAPID METHOD OF MEASURING THE METABOLISABLE ENERGY OF FEEDSTAFFS FEEDSTUFFS 52 (45) 24, 1980), based on free feed intake by the bird, devoid of most of these shortcomings. A feature of this method is the preliminary training of birds to consume their daily diet for 1 hour. To exclude the influence of the previous feed, the bird is not fed for 32 hours, and litter is collected within 32 hours after feeding. For better feed intake for the bird for 1 hour, this method uses granulation of the tested feed. The main advantage of this method is speed. However, it is necessary to constantly have a bird trained to consume a daily diet for 1 hour, which even after 2 weeks of training, the bird eats less than 1 hour of food than if consumed freely during the day. In the study of tasteless feed, their consumption may drop to 50 or less grams per head, which leads to the need to take into account endogenous secretions and the introduction of a recovery period for the bird.

 Closest to the claimed technical solution is a method for determining the exchange energy of feed Vohra P. etol (DETERMINATION OF METABOLIZABLE ENERGY BY A FAST METHOD, POULTRY SCI, 1982, 61, 766-769), which is selected as a prototype. To implement this method, they take a bird of the same age, with the same live weight, individually contained, trained to consume its daily diet in 1 hour. Before the control feeding, the bird is not fed 24-32 hours, and litter collection continues 48 hours after feeding. The feed and litter samples are dried to constant weight, after which their gross energies are determined and the exchange energy of the feed is calculated by the difference. With this method, it is not necessary to granulate the test food, which significantly reduces the complexity of preparing the feed mixture, but leads to a noticeable decrease in feed intake by the bird. An increase in the litter collection period to 48 hours is advisable, as studies have shown, only for some components of compound feeds, such as oats, feather flour, blood meal. For most easily digestible feeds, especially in case of low consumption, an increase in the litter collection period leads to an increase in the proportion of endogenous excretion in the total mass of excreta. The disadvantages of this method include the need to constantly have a bird trained to absorb a sufficient amount of feed in 1 hour; and low consumption of feed by poultry in the case of new, tasteless feeds makes it impossible to continuously use it without a recovery period.

 The basis of the invention the task is to increase the efficiency of the method for determining the exchange energy of feed by eliminating the disadvantages of the prototype.

 The technical result is achieved by increasing the poultry feeding period to 17-24 hours, thereby providing an increase in feed intake even if it contains tasteless ingredients. Thus, there is no need to take into account endogenous secretions in the total mass of excreta, which contributes to the accuracy of determining the amount of feed eaten and the excreted litter, and also allows the use of one bird continuously for testing various feeds without a recovery period.

 Long-term feed intake during the control period eliminates the need for a trained bird. The distribution of poultry into groups allows you to use different feeding modes to take into account the digestibility of various feeds.

 The problem is achieved by the method of determining the exchange energy of feed for poultry, mainly roosters, which consists in the fact that the same age, with the same amount of live weight, individually kept bird is limited to access to feed for 24-32 hours before the control feed, which is carried out by free consumption of feed poultry, collected litter is collected within 48 hours after the start of feeding, dried samples of feed and litter to constant weight, determine the values of gross drying energies of the samples and calculate the exchange energy of the feed, while forming two groups of equal number of birds, in one group the bird is allowed to feed for 17-18 hours, and in the other for 23-24 hours, in each group the average group ratio of dry matter masses is determined , allocated with the litter, to the one consumed with the feed, compare these relations between the groups and, if they are equal, use the averaged data on the consumed feed and the selected litter obtained in both groups to calculate the exchange energy of the feed, and in case of inequality, I’ll mention This relationship includes data for a group with a shorter duration of access to feed.

 From 24-48 hours to 31-48 hours are allotted for the passage of feed through the intestinal tract of the bird. To estimate the relative feed rate, the average relative litter allocation, i.e. the average group ratio of the masses of dry matter isolated with litter to that consumed with feed. For easily digestible feeds (the passage through the intestinal tract is less than 24 hours), due to the insignificant effect of the endogenous component of the excretions, these relations will be equal for both groups. Therefore, in this case, to calculate the exchange energy of the feed, you can use the averaged joint quantitative data on the consumed feed and the selected litter obtained in both groups. For indigestible feeds (passage time through the intestinal tract more than 24 hours), the indicated relations for groups with different feeding regimes will not be equal, and for a group with a long feeding period this ratio will be less due to a lack of time for complete litter isolation. Therefore, in this case, to calculate the exchange energy, quantitative data obtained only for the group with a shorter feeding period should be used.

 Examples of specific performance of the method.

 Example 1

Using the proposed method, the exchange energy of the full-feed compound PK-1 was determined, the composition of which is given in table. 1. The balance experiment was carried out in the conditions of the vivarium of the experimental farm VNITIP. As a model bird, 6 roosters of P-46 cross of 5-7 months of age with the same live weight were used, which were placed in individual cages equipped with separate feeders and drinkers. The experiment began at 9 o’clock in the morning of the first day, when all the roosters had their feed removed. After that, the bird was divided into 2 groups of 3 heads in each. At 15 o’clock the next day, all roosters were given 250 g of PK-1 food and at the same time, trays were placed under each cage to collect secretions, which were collected within 48 hours after the start of feeding. Water throughout the experiment was given without restrictions. At 9 o’clock on the third day, the food was removed from one group, and at 15 o’clock - from the other. By weighing the residues of feed, the quantitative consumption of feed was determined by the bird. In addition, at 15 o'clock they were replaced with clean pallets for collecting litter. At 3 p.m. on the fourth day, the quantitative collection of litter was completed and the balance experiment was completed. Then the feed and litter samples were dried at 60 ^° C. to constant weight. Quantitative data were obtained on consumption with feed and excretion of litter of dry matter by roosters of different groups, and the average relative allocation was determined for each group, i.e. the average group ratio of the mass of dry matter, isolated with litter, to consumed with feed, which are presented in table. 2. From the table. Figure 2 shows that the average relative emissions are almost equal for groups with different feeding periods, therefore, in the future, to calculate the exchange energy of feed, we used quantitative data obtained for both groups. The dried samples of feed and litter were ground, passed through a sieve with a hole diameter of 1 mm and pressed into weighed samples weighing 0.6 g, the gross energies of which were determined by burning in an adiabatic oxygen bomb calorimeter OQ-10171/225 and were equal to 14.90 and 11 , 31 kJ / g, respectively. According to these data and table. 2, the exchange energy of the feed was calculated, which turned out to be 11.00 kJ / g. For comparison, the exchange energy of PK-1 compound feed was estimated using the traditional method and a value of 11.16 kJ / g was obtained, which is in good agreement with the value obtained by the proposed method.

 Example 2

Using the proposed method, the exchange energy of oats was determined. The balance experiment was carried out in the conditions of the vivarium of the experimental farm VNITIP. As a model bird, 6 roosters of P-46 cross of 5-7 months of age with the same live weight were used, which were placed in individual cages equipped with separate feeders and drinkers. The experiment began at 9 o’clock in the morning of the first day, when all the roosters had their feed removed. After that, the bird was divided into 2 groups of 3 heads in each. At 15 o’clock the next day, all roosters were given 250 g of oat mono-feed and, at the same time, trays were placed under each cage to collect secretions, which were collected within 48 hours after the start of feeding. Water throughout the experiment was given without restrictions. At 9 o’clock on the third day, the food was removed from one group, and at 15 o’clock - from the other. By weighing the residues of feed, the quantitative consumption of feed was determined by the bird. In addition, at 15 o'clock they were replaced with clean pallets for collecting litter. At 3 p.m. on the fourth day, the quantitative collection of litter was completed and the balance experiment was completed. Then the feed and litter samples were dried at 60 ^° C. to constant weight. Quantitative data were obtained on consumption with food and excretion of dry matter by roosters of different groups with litter, and in each group the average relative excretion, i.e., the average group ratio of the masses of dry matter excreted with litter, to consumed with food, which are presented in Table . 3. From the table. Figure 3 shows that the average relative discharge in groups with different periods of feeding is different, therefore, for further calculations, the data obtained in group 1 were used. The dried feed and litter samples were ground, passed through a sieve with a hole diameter of 1 mm and pressed into weighed samples weighing 0.6 g, the gross energies of which were determined by burning in an adiabatic oxygen bomb calorimeter OQ-10171-225 and were equal to 18.29 and 14 , 25 kJ / g, respectively. According to these data and table. For group 1, the exchange energy of oats was calculated, which turned out to be equal to 14.33 kJ / g. In the works of DJ Farrell. An assessment of quick bioassays for determining the true metabolizable energy and apparent metabolizable energy of poultry feedstuffs. / World's Poultry Sci. Journal, v. 37, No. 2, 1981, p. 72-83; and MJ Schang and RMG Hamilton. Comparison of two direct bioassays using abult cocks and four indirect methods for estimating the metabolizable energy content of different feedingstuffs. Poultry Sci. (1982) 61: 1344-1353; values of 13.99 and 14.33 kJ / g, respectively, were obtained for the exchange energy of oats.

Claims (2)

 1. A method for determining the exchange energy of feed for poultry, mainly roosters, including the individual keeping of an even-aged bird with the same live weight, free access to the test feed after a period of restriction of access to it for 24-32 hours, collecting isolated litter for 48 hours after the start of access to the feed, the determination of the gross energy of the test feed and litter in their samples, dried to constant mass, and the calculation of the exchange energy, characterized in that they form two equal in number fr groups, one of which is freely allowed to feed for 17-18 hours, and the other for 23-24 hours, for each group, the ratio of the dry matter mass of the selected litter to the dry matter mass consumed by the feed groups is determined, the average ratios between the groups are compared and , if they are equal, to calculate the exchange energy of the test feed, use the averaged data for both groups, and in case of inequality of the mentioned relations, data for the group with a shorter duration of access to the feed.  2. The method according to claim 1, characterized in that the bird, when used continuously to determine the exchange energy of the feed, provides free access to it when giving a doubled feed rate every other day.

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