RU2078519C1 - Food addition - Google Patents

Abstract

FIELD: agriculture. SUBSTANCE: method involves feeding the food addition to animals and poultry (twice per 24 h) the following composition, % by mass: food yeast 5-25; fish flour 4-10; vitamin A 0.007-0.01; vitamin D 0.001-0.009; vitamin E 0.002-0.003; vitamin B₂ 0.0002-0.004; vitamin B₃ 0.01-0.03; vitamin B₄ 0.07-0.16; vitamin B₁₂ 0.00000-0.000003; santoquine 0.001-0.005; biomycin 0.001-0.006; iron 0.01-0.02; copper 0.001-0.003; cobalt 0.0002-0.0004; iodine 0.0001-0.0003; zinc ascorbate 0.02-1.8, and pea extrudate 90.88-62.95. EFFECT: enhanced effectiveness of food addition. 8 tbl

Description

 The invention relates to agriculture, in particular to the feeding of farm animals and poultry.

Known diets containing ascorbic acid in their composition. The addition of 10 193 mg per 100 kg of live weight of ascorbic acid to sows rations contributes to a more even litter with better growth energy. The lower level of ascorbic acid in sows milk is one of the causes of death of sucking pigs. So reducing the level of ascorbic acid in milk to 12 leads to a sharp increase in the death of piglets [1]
Closest to the invention is a mineral additive containing macro- and microelements, in particular zinc sulfate, copper sulfate, manganese sulfate, cobalt nitrate, potassium iodide. Feeding a complex supplement made it possible to balance animal diets according to the basic elements of mineral nutrition, while the average daily gain in live weight is increased by 22 52 g or 4.3 6.9 [2]
A disadvantage of the known rations and additives is the lack of optimal doses of ascorbic acid and trace elements, in particular zinc, for different types of farm animals and poultry, low absorption of ascorbic acid and inorganic derivatives of zinc by the body, a slight improvement in productivity indicators, which amounted to 4.3 6 in the given example. 9 compared to control.

 The purpose of the invention is to increase the productivity and preservation of the livestock of animals and poultry, reducing feed costs for products.

This goal is achieved by the fact that a feed additive for farm animals and poultry containing pea extrudate, fodder yeast and fish meal, vitamins A, D, E, B ₂ , B ₃ , B ₄ , B ₁₂ , Santokhin, biomycin, iron, copper , cobalt, iodine, further includes zinc ascorbate and has the following ratio of components, wt.

Fodder yeast 5 25
Fishmeal 4 6
Vitamins
A 0.007 0.010
D 0.001 0.009
E 0.001 0.004
B ₂ 0.0002 0.0004
B ₃ 0.010 0.030
B ₄ 0.070 0.160
B ₁₂ 0.000001 0.000003
Santokhin 0.001 0.005
Biomycin 0.001 0.006
Iron 0.01 0.02
Copper 0.001 0.003
Cobalt 0.0002 0.0004
Iodine 0.0001 0.0003
Zinc ascorbate 0.002 1.800
Pea Extrudate Else
The novelty of the proposed feed additive is that in order to increase the productivity and safety of the livestock, reduce feed costs for growth and improve product quality, zinc ascorbate is also introduced into the composition of the feed additive as a biogenic preparation.

 Examples of specific performance.

 To confirm the effectiveness of this feed additive for farm animals and poultry, studies were carried out on the reproductive pig and dairy complexes of the collective farm named after Frunze, as well as the May poultry farm of the Belgorod region and the reproductive pig farm of the Druzhba collective farm in the Yakovlevsky district of the Belgorod region.

 Experimental data on the use of the proposed feed additive were obtained in two experiments on 8 groups of suckling pigs in the amount of 103 and 140 goals, experiments on broiler chickens of 1200 goals, laying hens of 420 goals, heifers at the age of 4 months, 40 goals and milking cows 32 heads.

 The main diets of the control and experimental groups included standard compound feeds: for pigs K-50-17, for poultry PK-5 and PK-6, cattle K-60-33-89. The main components of standard compound feeds were barley, corn, oats, wheat bran.

The animals and poultry of the I (control) group were fed the main diet throughout the entire period with the introduction of a feed additive in an amount of 25 from the main diet of the following composition, wt. sunflower meal 74.8, feed yeast 25.0; vitamin A 0.03; vitamin D 0.04; vitamin E 0.002; vitamin B ₂ 0.003; Vitamin B ₃ 0.01; Vitamin B ₄ 0.12; Vitamin B ₁₂ 0.000002; Santokhin 0.004; biomycin 0.002; iron 0.03; copper 0.005; cobalt 0.0002; iodine 0,0002; zinc (zinc sulfate) 0.009.

The animals and poultry of the experimental group II were fed the main diet throughout the experiment with the introduction of 20 proposed feed additives of the following composition, wt. feed yeast 5.0; fishmeal 4.0; Vitamin A 0.007; Vitamin D 0.001; Vitamin E 0.001; Vitamin B ₂ 0.0002; Vitamin B ₃ 0.01; Vitamin B ₄ 0.07; vitamin B ₁₂ 0.000001; Santokhin 0.001; biomycin 0.001; iron 0.01; copper 0.001; cobalt 0.0002; iodine 0.001; zinc ascorbate 0.02; pea extrudate 90.88.

The experimental animals and poultry of the III experimental group were fed the main diet with the introduction of 25 of the main diet of the proposed feed additive of the following composition, wt. feed yeast 15.0; fish meal 7.0; vitamin A 0.009; vitamin D 0.005; vitamin E 0.002; Vitamin B ₂ 0.01; Vitamin B ₃ 0.02; Vitamin B ₄ 0.10; Vitamin B ₁₂ 0.000002; Santokhin 0.003; biomycin 0.003; iron 0.015; copper 0.6002; cobalt 0.0003; iodine 0,0002; zinc ascorbate 0.60; pea extrudate 77.22.

During the experiment, animals and poultry of the IV experimental group were fed the main diet with the introduction of 30 proposed feed additives from the main diet of the following composition, wt. feed yeast 25.0; fish meal 10; Vitamin A 0.01; vitamin D 0.009; E 0.003; vitamin B ₂ 0.004; Vitamin B ₃ 0.03; Vitamin B ₄ 0.16; Vitamin B ₁₂ 0.000003; Santokhin 0.005; biomycin 0.006; iron 0.02; copper 0.003; cobalt 0.0004; iodine 0,0003; zinc ascorbate 1.8; pea extrudate 62.95.

 The use of zinc ascorbate, fishmeal, and fodder yeast in the composition of the feed additive helps to increase the productivity of animals and poultry, their safety, reduce the cost of feed for products, increases its quality (see table. 1, 4, c).

 Analysis of the results of studies on suckling pigs (experiment 1) showed that the introduction of the proposed feed additive in the amount of 20 from the main diet into the composition of the main diet of the II experimental group did not affect the productivity of piglets. The live weight of the piglets at weaning was lower by 2.5 compared with the control group. The inclusion in the main diet of piglets of the III experimental group of the feed additive in the amount of 25 from the main diet contributed to an increase in live weight of piglets by weaning by 1.12 kg or 16.7 (p 0.95), and the average daily gain in live weight of piglets was 225 g and was higher than in the I control group by 56 g or 33.1 with a significant difference (p 0.99) (see table. 1).

 Due to the higher growth intensity, an additional 30.2 kg of weight gain was additionally obtained in the group.

 Feeding a feed additive in the diet of experimental group IV in an amount of 30 from the main diet increased the live weight of piglets by weaning by 7.6% (0.51 kg), while the growth rate increased by 14.8 (25 g) compared to the control I group. An additional gain of 12.7 kg was obtained.

 When using a feed additive in the diets of weaned pigs (experiment III), it was found that the highest growth rate of animals was observed in experimental group III when using a feed additive in the main diet in an amount of 25 with a content of zinc ascorbate in a dose of 0.6 the average daily gain in live weight of group III piglets exceeded the control by 17 (63 g) with a decrease in feed costs for growth by 8.3 (see table. 2).

Thus, the most effective in both the first and second experiments was an additive in the amount of 25 from the main diet with a dose of 0.6 of zinc ascorbate
The experimental results showed that in the composition of the feed additive for piglets, the most optimal dosage of zinc ascorbate is 0.6
Analysis of the results of studies on broiler chickens (experiment III) showed that the use of the proposed feed additive in the diet had a positive effect on the productivity and safety of poultry, and meat quality.

From the data table. 3 shows that the increase in live weight of broiler chickens in all experimental groups was higher than in the first control. The highest growth rates of live weight of chickens were obtained in the III experimental group of broiler chickens, in the diet of which the feed additive was introduced in the amount of 25 from the main diet, chickens in this group were superior in live weight to peers from the control group 12.1 The average daily gain was higher by 12.4 than in the chickens of the control group with a significant difference (p 0.05). In terms of feed costs per 1 kg of growth, broiler chickens exceeded peers from the control group by 13
The broilers of the IV experimental group, who were prescribed a feed supplement at a dose of 30 from the main diet, also significantly exceeded the control chickens in live weight by the end of the cultivation and in growth intensity by 5.3. The feed costs per growth unit in the IV experimental group were lower by 4.6 than in the control group.

When analyzing the data on the safety of the livestock, it was found that during the growing period this indicator in the control group was 88.7, and in the second experimental group, 91.0, which is 2.3 higher than in the control group. The highest safety of the poultry was in the III experimental group and amounted to 98.3, which exceeded the control group by 9.6. Broiler chickens of the fourth experimental group also exceeded the control group by safety by 6
At 56 days of age, a control slaughter of chickens of all groups was carried out in order to study the chemical composition and quality of meat. Analysis of the data obtained (see table. 4) showed that the quality of the meat of chickens of all experimental groups significantly exceeded that of the control group. Thus, the content of dry matter in the meat of chickens of the experimental groups of the dry matter was higher by 11.0 19.8 protein by 4.0 1.5 fat by 14.0 18.8 than in the meat of chickens from the control group. Protein-quality indicator of meat of chickens II; III and IV of the experimental groups was higher than in the control, respectively, by 9.6; 20.5 and 22.6 with a significant difference (o 0.05 and p 0.01).

 When examining the liver of experimental broiler chickens at the end of the cultivation, it was found that the level of ascorbic acid (vitamin C) in broilers of the II, III, and IV experimental groups was higher than in the control with a highly significant difference of 27.2, 60.4, and 58, respectively , 8 (p 0.01), which indicates the high bioavailability of ascorbic acid from zinc ascorbate.

 The concentration of zinc in the liver of the experimental bird depended on the dose of zinc ascorbate in the feed additive and was almost similar to the accumulation of ascorbic acid, which indicates the best bioavailability of this trace element from zinc ascorbate. It should be noted that the deposition of vitamin A in the liver of broiler chickens of the experimental groups also exceeded the control: in the II experimental group by 27.7, III 28.5 and IV 38.6 with a highly reliable difference (p 0.001). The fact of the best assimilation of vitamin A in broilers of the experimental groups can be explained by the fact that zinc is one of the main factors regulating the efficiency of using vitamin A in the metabolic process and its bioavailability from zinc ascorbate is the highest.

 As a result of biochemical blood tests, it was found that metabolic processes in the body of the bird of the experimental groups proceeded in a more optimal mode. So the level of total protein in serum from the control group at 15.2 of the III experimental group at 20.5 and IV at 23.7 with a significant difference (0 0.01; p 0.001 and p. 0.001, respectively) (see table. 5).

 By the content of red blood cells, as well as their saturation with hemoglobin, the chickens of the experimental groups exceeded the peers from the control group.

 Thus, from the above results of studies on poultry, it can be concluded that the use of zinc ascorbate in the composition of the feed additive has a positive effect on increasing the productivity of broiler chickens, reduces the cost of feed for products, increases the safety of the livestock and meat quality. For poultry, the optimal content of zinc ascorbate in the feed additive is 0.60 mass.

 Studies of the effectiveness of using the proposed feed additive in the main diet were carried out on heifers for 60 days (experiment IV).

 The use of various amounts of zinc ascorbate in the composition of the feed additive had a definite effect on the growth and development of heifers. The cost of feed for weight gain (table. 6).

The highest gain in live weight was obtained in animals of the IV experimental group and exceeded that in the control group by 26 with a significant difference (p 0.05), and feed costs per 1 kg of weight gain were lower by 20
Feeding the proposed feed additive in an amount of 25 from the main diet contributed to an increase in the average daily gain in live weight in heifers of the III experimental group by 7 while reducing the cost of feed by 1 kg of weight gain by 12
Studies on the use of feed additives in diets were also carried out on lactating cows (experiment V). The results presented in table. 7 show that the use of a feed additive in the diet of lactating cows in an amount of 25 and 30 by weight of the main diet and the inclusion of zinc ascorbate in a dose of 0.6 and 1.8 in the feed additive contributed to an increase in milk yield in cows of the III and IV experimental groups by 11 and 4,5 At the same time, chemical and biological analyzes of milk showed that its quality in the III and IV experimental groups significantly increased compared to the control. Thus, zinc ascorbate in the composition of the feed additive in doses of 0.6 and 1.8 contributed to an increase in the vitamin value of milk, since the content of carotene in it increased in the II experimental group by 14, in III by 72 and in IV by 27 vitamin A in experimental III group 23, IV IV 18 vitamin C in the II experimental group 1.1, III III 29 and IV IV 20 compared with the control group (see table. 7).

 In addition, zinc ascorbate in the composition of the feed additive has the properties of a denitrifying substance. This is convincingly illustrated in the table. 7, which shows the beneficial effect of zinc ascorbate on the nitro-reducing system of the body, since a statistically significantly lower amount of nitrates and nitrites was found in the milk of cows of all experimental groups (II, III, and IV). So the content of nitrates and nitrites in cow's milk in the II experimental group was less by 12.1, in III by 46.6 and in IV by 43.5 than in the control group, and nitrites, respectively, were lower in II by 28.6, in III by 42.9, and in IV by 28.6 The content of ammonium derivatives was also lower in the milk of cows of the experimental groups. So the ammonia content in milk of the II experimental group was lower by 39.9, III 41.6 and IV 48.8 in comparison with the milk of the control group.

 A positive moment is the effect of zinc ascorbate in the composition of the feed additive on the decrease in the milk of cows of the experimental groups in comparison with the control compound of heavy metals of copper, cadmium, lead. Moreover, for lead, this decrease was significant.

 Biochemical studies of cow blood showed that under the influence of zinc ascorbate in its composition in the experimental groups the following changes occurred. The concentration of nitrates in the blood of cows of the experimental groups was lower by 42–74 compared with the control (the differences were statistically significant) (see Table 8). Methemoglobin and nitrites were found only in the blood of cows of the control group. All this fully confirms the denitrifying effect of zinc ascorbate in the body of cows as part of a feed additive.

 Thus, it can be seen from the above data that the use of the proposed feed additive in the main diet for cattle (heifers and cows) in the amount of 25 and 30 from the main diet, as well as the introduction of zinc ascorbate as a biogenic preparation and denitrifying agent in the composition of the feed additive substances, helps to increase the productivity of animals (increase in average daily gain in live weight in heifers and reduce feed costs for growth, increase milk yield of cows), improve milk quality (increase in content I vitamins in milk, a significant decrease in milk of nitrates, nitrites, ammonia, salts of heavy metals of copper, cadmium, lead), increases the economic indicators of weight gain.

 Technical and economic efficiency.

 Analysis of economic indicators indicates that the use of the proposed feed additive in the composition of the main diet for farm animals and poultry in the amount of 20, 25 and 30 from the main diet contributes to an additional increase in live weight and reduce feed costs for growth.

Thus, from the data presented, it can be concluded that the proposed feed additive has novelty and advantage compared to the control group, the animals and poultry of which received a standard feed additive and standard feed for the following main indicators:
composition of the feed additive;
productive action;
livestock safety;
chemical composition, biological usefulness and quality of meat and milk;
denitrifying action.

Claims (1)

A feed additive containing potassium iodide, copper sulfate, cobalt and zinc salts, characterized in that as cobalt and zinc salts it contains cobalt carbonate and zinc ascorbate and additionally ferrous sulfate, biomycin, santokhin, fodder yeast, fish meal, vitamins A, D, E, B ₂ , B ₃ , B ₄ , B ₁₂ and pea extrudate in the following ratio of components, wt. Fodder Yeast 5 25
Fishmeal 4 10
Vitamins:
A 0.007 0.01
3 0.001 0.009
E 0.002 0.003
B ₂ 0.0002 0.004
B ₃ 0.01 0.03
B ₄ 0.07 0.16
B ₁₂ 0.000001 0.000003
Santokhin 0.001 0.05
Biomycin 0.001 0.006
Iron sulfate 0.01 0.02
Copper sulfate 0.001 0.003
Cobalt carbon dioxide 0.0002 0.0004
Potassium iodide 0.0001 0.0003
Zinc ascorbate 0.02 1.8
Pea extrudate

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