RU2050141C1 - Hens feeding method - Google Patents

Abstract

FIELD: agriculture; poultry farming. SUBSTANCE: method involves supplementation of poultry feed with some polymer surfactant (3-7 mg) and magnesium ions (6-12 mg/kg of liveweight). The surfactant is substance obtained by dissolving (in water) of copolymer of vinyl pyrrolidone with iodine ethylate of diethylaminoethyl methacrylate (structural formula presented in the description). The proportion of ingredients is as follows (% mass): copolymer 0.0157-0.0188, sodium alkyl phosphate 0.0212-0.0287, magnesium sulfate 1.11- 2.22, water the rest. EFFECT: higher quality of poultry products. 3 tbl

Description

 The invention relates to a method for feeding chickens using polymer additives containing surfactants and inorganic salts.

 Known methods of feeding chickens with the addition of low molecular weight surfactants of various structures: cationic, anionic and nonionic.

R

OH

C-R где R С_nН_2n+1 (n 6-24); R₁, R₂, R₃ CH₃-; C₂H₅-; R₄, R₅, R₆, R₇ H^-; CH₃ ^-.A known method of feeding chickens with the introduction into the feed of 0.02-5.0% of cationic surfactants Quaternary ammonium salts of amino alcohols (1) of the General formula:

R

OH

CR where R C _n H _{2n + 1} (n 6-24); R ₁ , R ₂ , R ₃ CH ₃ -; C ₂ H ₅ -; R ₄ , R ₅ , R ₆ , R ₇ H ^- ; CH ₃ ^- .

When such surfactants are introduced into the feed for 4-8 weeks, the increase in poultry live weight does not exceed 3.5-5%
More effective were the methods of feeding chickens using an anionic surfactant called "Alanate" as an additive, which is a mixture of low molecular weight secondary sodium alkyl sulfonates with an alkyl chain containing C ₁₁ -C ₁₇ .

When fed for 4-8 weeks at a dose of 50-100 mg per 1 kg of live weight of chickens, their average daily increase increases by 12-30%
A disadvantage of the known methods of feeding chickens is the use of low molecular weight surfactants as additives, which are toxic, easily penetrate from the intestines into the bloodstream and, when they enter organs and tissues, degrade the quality of poultry products.

 The aim of the invention is to give the ability of feed additives not to be absorbed by the intestinal surface, which prevents their accumulation in the body of the bird and, thereby, improves the quality of poultry products.

CH

H

с ММ (23-100)˙10³ Да, где m 15-20 мол.The goal is achieved by the method of feeding chickens, which is characterized by a combination of the following features:
sequentially dissolve in water a copolymer of vinyl pyrrolidone with diethylaminoethyl methacrylate iodo ethylate of the general formula:

CH

H

with MM (23-100) ˙10 ³ Yes, where m 15-20 mol.

 n 80-85 mol.

sodium alkyl sulfate of the general formula
C _p H _{2p + 1} OSO ₃ Na where p is 12-16, and magnesium sulfate.

 The ratio of the components is as follows, wt.

Copolymer 0.0157-0.0188
Alkyl Sulfate
sodium 0.0212-0.0293
Magnesium Sulphate 1.11-2.22
The remaining water is up to 100.

 The resulting aqueous solution is added to chicken feed in an amount of 3-7 mg of a copolymer complex with sodium alkyl sulfate and 6-12 mg of magnesium ions per 1 kg of live weight of chickens.

 The presence of a new property of the known substance is additionally confirmed in the discovery of such a function of this complex as the ability to increase the egg production of chickens, improve the incubation properties of eggs, increase the viability of chickens, and also show a stimulating effect after cancellation for 2 months.

 Most effects occur only when feeding the bird. The influence of these complex stimulants on the productivity of laying hens and on the quality of eggs is presented in Tables 1-3, where the characteristics of sodium copolymers and alkyl sulfonates are given, on the basis of which polymer derivatives of surfactants are obtained.

 The synthesis of polymers was carried out in a known manner by the radical copolymerization of N-vinylpyrrolidone (VP) and N, N-diethylaminoethyl methacrylate (DEAEMA) in isopropyl alcohol using azoisobutyric acid as a radical initiator.

 The resulting VP-DEAEMA copolymer is quaternized by treatment with ethyl iodide.

After distillation of isopropyl alcohol, the copolymer of VP and DEAEMA iodoethylate is dissolved in water and isolated in powder form by spray drying. As sodium alkyl sulfonates, compounds with a purity of ≈99% with C ₁₂ -C _{16 are used} .

PRI me R 4. In a reaction vessel equipped with a stirrer, reflux condenser and a thermometer integrated inside, load by weight 23.02 g of vinyl pyrrolidone (0.206 mol), 9.74 g of diethylaminoethyl methacrylate (0.052 mol) and 0.328 g of azoisobutyronitrile. 121.5 g of isopropanol are added to the resulting solution and nitrogen gas is bubbled through the solution to remove dissolved oxygen. Turn on the heating of the reactor and carry out the polymerization at 65 ^about With stirring for 18 hours. Get a copolymer of vinylpyrrolidone and diethylaminoethyl methacrylate composition 83:17 mol. with MM 88000.

To a solution of the copolymer was added 8.85 g of ethyl iodide and at ⁶⁵ ° C and stirring for 8 hours kvarternizatsiyu lead, and then thereto was added 198.4 g of a 30% aqueous solution of sodium dodecyl sulfate. Hydroalcoholic solution was heated with stirring under vacuum (10-15 mm Hg) and distilled at 45-50 ^{° C} isopropanol in an amount of 140 ml (110.5 g).

Then, another 161.7 g of distilled water is added to the residue in the reactor and the solution is evaporated in vacuo to the concentration of the target product) a complex of copolymer and sodium dodecyl sulfate with a component ratio of 43.4: 56.6 wt.) About 30%
Then, the resulting solution was diluted with an equal volume of distilled water and dried by spraying or lyophilized, to obtain 100 g of stimulator (yield 97%) in the form of a powder.

 Characteristics are given in table 1.

 Examples 1-12 are made under the conditions of example 4.

 Example 12. An aqueous stimulant solution containing 0.0267% hexadecyl sulfate 0.0188% copolymer and 2.22% magnesium sulfate was introduced into the feed ration in the volumes indicated in Example 5.

 In this case, the dose in the copolymer complex was 8 mg / kg, and in magnesium ions 12 mg / kg.

 For 1 month egg production of chickens increased by 20.6% and live weight of 1 head from 1.76 to 1.93 kg (i.e. by 9.6%).

 PRI me R 13. An aqueous solution of a complex stimulant containing 0.0247% sodium hexadecyl sulfate, 0.0174% copolymer and 2.22% magnesium sulfate, was introduced into the poultry diet in the conditions of example 4.

In this case, the dose for the copolymer complex was 5.26 mg / kg, and for magnesium ions 12 mg / kg of live weight of chickens. For 1 month in poultry, egg production increased by 21.4% and live weight increased from 1.81 kg to 2.01 kg, i.e. 11.1%
PRI me R 1. To assess the effect of copolymer complexes on the bird selected on the basis of the analogues of the group of laying hens of the breed "Belarus-9" 5-6 months of age, 33 heads in each group.

 The hens of the control group received the main diet (95% of feed 3-4 and an additional 5% premix 3), and the hens of the experimental groups additionally included a complex stimulant in the diet.

 In the control group, the bird with the maximum egg production was selected (on average 24 eggs / month per head before the start of the experiment).

During the reference period (1 month), the egg production of hens in the control group decreased and amounted to 21.5 eggs / head, i.e. fell by 10.5%
The increase in live weight for this period amounted to 60 g / goal. those. the mass of chickens increased by 3.3%
PRI me R 2. Chickens of the experimental group with food 1 time per day for a month was given a water-salt solution of a complex stimulant containing 0.0226% sodium dodecyl sulfate, 0.0174% copolymer and 2.22% magnesium sulfate. The stimulant was administered in a volume of 2.5 ml per 1 kg of live weight. In this case, the daily dose for the copolymer complex was 1 mg / kg m and for magnesium ions 12 mg / kg m During the reference period (1 month), live weight of the bird increased by 5% and egg production by 33.9%
PRI me R 3. An aqueous solution of a stimulant containing 0.0243% sodium dodecyl sulfate, 0.0157% copolymer and 2.22% magnesium sulfate, was introduced into the chickens feed in a volume of 7.5 ml per 1 kg g.m. poultry, or at a dose of 3 mg / kg (copolymer complex) 12 mg / kg (magnesium ions). For 1 month egg production of chickens increased by 19% and live weight from 1.81 kg to 1.93 kg, i.e. 6.6%
PRI me R 4. An aqueous solution containing 0.0226% sodium dodecyl sulfate, 0.0174% copolymer and 2.22% magnesium sulfate, was introduced into the diet of chickens in a volume of 12.5 ml per 1 kg m which corresponded to a daily dose of 5 mg (for the copolymer complex) and 12 mg (for magnesium ions). During the reference period (1 month), the laying capacity of chickens increased by 22.1% and live weight per head from 1.82 kg to 2.04 kg, i.e. 12.1%
PRI me R 5. An aqueous solution of a stimulant containing 0.0212% sodium dodecyl sulfate, 0.0188% copolymer and 2.22% magnesium sulfate, was introduced into the poultry diet in a volume of 17.5 ml per 1 kg g.m . or at a dose of 7 mg / kg for the copolymer complex and 12 mg / kg for magnesium ions. Over a one-month course of stimulation, hens increased egg production by 24.0% and live weight by 15.4% (from 1.75 kg to 2.02 kg).

PRI me R 6. When you include the complex stimulator according to example 5 in the diet of chickens, but in a larger volume (22.5 ml per 1 kg g.m.), i.e. in daily doses for the copolymer complex 9 mg / kg and magnesium ions 12 mg / kg, the egg production of chickens increased by 14.2% and their live weight by 7.1%
PRI me R 7. Feeding chickens complex stimulator in the conditions of example 2, but when using an aqueous solution containing a greater amount of magnesium sulfate (2.78%) provided a less stimulating effect. Egg production of chickens for 1 month. increased by 20% and live weight by only 4.5% (from 1.76 kg to 1.84 kg).

PRI me R 8. The inclusion of the stimulator according to example 2 in the feed diet of chickens, but when using half the concentration of magnesium sulfate (1.11%) provided an increase in egg production by only 14.3% and a slight increase in gain in live weight by 4 3%
PRI me R 9. Feeding the stimulator according to example 2, but when using a lower concentration of magnesium sulfate (0.93%), ie at a dose of 5 mg / kg of magnesium ions, it provided an increase in the egg production of chickens by only 11% and a slight increase in live weight of chickens by 4% (from 1.76 to 1.83 kg).

 PRI me R 10. Feeding chickens of magnesium sulfate in a daily dose of 12 mg / kg of magnesium ions without the inclusion of a copolymer complex in the diet did not affect the productivity of chickens. Egg production of hens, as in the control group, fell by 15% and live weight increased by 60 g (3.3%).

 PRI me R 11. The introduction of the copolymer complex according to example 4 in the diet of chickens, but without the addition of magnesium sulfate, increased the egg production of chickens by 7% and live weight by 4% (from 1.82 to 1.90 kg).

 PRI me R 14. When you include the complex stimulator according to example 4 in the diet of 900 laying hens, starting from 5-6 months of age for 8 months. with a two-month break, the egg production of hens increased over the entire period by 17.2% compared with the control. For the first month from the start of the stimulation course, the egg production of hens in the experimental group amounted to 728.6 pcs. and in the control group 605.8 pcs. those. 20.3% more. For the second month, the egg production of hens in the experimental group amounted to 682 pcs. and in the control 568.6 pcs. those. 20.1% more.

 After the termination of feeding the stimulator during the 3rd and 4th month of the experiment, the egg production of the hens of the experimental group decreased, but exceeded the control indices by the end of the 3rd month by 19.9% and by the end of the 4th month by 8.1.

 The resumption of feeding the stimulator during the 5th and 6th month from the beginning of the experiment sharply increased the egg production of the bird, which amounted to 692 pieces by the end of the 5th month in the experimental group. and in control 520 pcs. those. 33.1% more than in control.

By the end of the 6th month, the egg production of the hens of the experimental group exceeded the control indicators by 12%
When the drug was canceled during the 7th and 8th months of the experiment, the egg production of the hens of the experimental group decreased to 671 pcs. (end of 7 months) and 575.6 pcs. (end of 8 months), but exceeded the egg production of hens in the control group by 8.6 and 4.7%, respectively
PRI me R 15. Eggs obtained from poultry of the experimental and control groups receiving the stimulant in example 12, were evaluated by such indicators as weight, shell thickness and nutritional value (see table 2). In a bird that underwent a course of stimulation, the average weight of 1 egg increased by 7.2% compared to the control by a shell thickness of 3.4-10.7% and nutrition by 21% (carotenoids), 7.4% (vitamin A), and 16.1% (vitamin B).

PRI me R 16. Evaluation of the incubation properties of eggs obtained in the conditions of example 12 and the hatchability of chickens showed (table 3) that the hatchability of chickens from eggs of birds treated with a stimulant is higher than in the control by 7.6% a the safety of chickens exceeds the control indicators by 12.3%
The analysis of examples of specific implementation showed that by varying the compositions and molecular characteristics of the copolymer complexes within the limits stated in the invention, the inclusion of these substances in the feed ration of laying hens in doses of 3 to 7 mg per 1 kg of live weight provides an increase in bird productivity.

 When the dose is reduced to 1 mg / kg, the stimulating effect of the copolymer complexes decreases sharply. When the dose is increased to 9 mg / kg, despite the increase in the productivity of chickens, the morphological and biochemical parameters of the blood of chickens deteriorate (the hemoglobin level, the number of red blood cells decreases, the number of leukocytes increases, the total protein level decreases and the gamma level decreases -globulins).

 The range of doses of magnesium sulfate is determined by the existence of an upper limit (a dose of 12 mg / kg for magnesium ions is the normal physiological daily requirement for this macrocell), and a lower limit of 6 mg / kg, since when the dose of magnesium ions is reduced to 5 mg / kg (example 9) complex stimulator dramatically reduces its effectiveness.

 The effect of complex stimulants on the bird is characterized by the presence of the effect of the consequences after they are canceled within 2 months.

 In addition, the positive effect of the proposed technical solution is complemented by improving the quality of the resulting poultry products (examples 13 and 14).

Toxicological evaluation of copolymer complexes on poultry showed that they belong to low-toxic substances (LD ₅₀ 7200 mg / kg, MPD 7000 mg / kg, LD ₁₀₀ 10000 mg / kg). When studying the subchronic toxicity of these substances, it was found that the copolymer complexes do not possess cumulative properties (coefficient of cumulation 8.53), as well as in doses of 0.5; 0.1 and 0.01 LD ₅₀ do not have embryotoxic and teratogenic effects.

 When studying the pharmacokinetics of copolymer complexes using radioactive labels, it was found that the copolymer is not absorbed into the blood from the intestine and is excreted 100% from the body in 72 hours.

 Alkyl sulfates undergo biodegradation to gamma oximebutyric acid (the final metabolite) and completely leave the body after 48 hours.

 In stimulating doses (3-7 mg / kg), copolymer complexes have a positive effect on blood hematopoiesis, the formation of red blood cells, as well as lipid and carbohydrate metabolism in birds.

Claims (1)

METHOD FOR FEEDING CHICKEN by introducing into the main diet a feed additive containing a surfactant, characterized in that the substance obtained by sequentially dissolving in water a vinylpyrrolidone-iodo-ethylate diethylamino-ethyl methacrylate copolymer is used as a surfactant

where m 15 20;
n 80 85 mol. with a mol.m. 23,100 · 10 ³ Yes;
sodium alkyl sulfate of the general formula C _p H _{2 p + 1} OSO ₃ Na, where p 12 16 and magnesium sulfate in the following ratio, wt. Copolymer 0.0157 0.0188
Sodium Alkyl Sulfate 0.0212 0.0287
Magnesium Sulfate 1.11 2.22
Water Else
introducing into the main diet a feed additive containing 3 7 mg of surfactant and 6 12 mg of magnesium ion per 1 kg of live weight of chickens.

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