RU1819143C - Method for balancing rations of cattle by magnesium - Google Patents

Abstract

Usage: in agriculture, in the processes of fodder production with a balanced content of magnesium and sulfur. SUMMARY OF THE INVENTION: to increase the productivity of animals, a mineral supplement, potassium magnesia, is added to their feed, which is administered at a dose of 0.15-0.25 g per 1 kg of live weight of the animal. 7 tab.

Description

The invention relates to agriculture, in particular to the use of mineral feed additives that increase the productivity of farm animals.

The purpose of the present invention is to expand the range of magnesium and sulfur-containing feed additives, increase their availability for wider use in animal husbandry, reduce the cost of these additives and increase their efficiency, reduce the cost of known magnesium and sulfur-containing feed additives, in particular magnesium sulfate in livestock, which makes it possible for their wider use in other sectors of the national economy.

This goal is achieved by the use of a previously known product for feeding animals - potassium magnesia “2S04-MgS04 6H20, containing magnesium

and sulfur, and so far used in agriculture as potash and magnesium mineral fertilizer.

An analysis of known technical solutions has shown that the use of potassium magnesia as - and with a sulfur-containing feed additive is not known at all. The proposed solution meets the criterion of significant differences, since it is characterized by a new set of features.

Potassium magnesia is a gray, odorless powder.

In order to determine the possibility and harmlessness of potassium magnesia for use as a feed additive for animals, we studied its hollow chemical composition, in particular, the content of magnesium and sulfur, most other macro- and microelements, as well as elements

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heavy metals (lead, mercury, tin, mouse, cadmium, chlorine and others), the deposition of which in various organs and tissues of animals could cause their chronic or acute poisoning. Determination - the content of magnesium and a number of others in potassium magnesia macro- and microelements of heavy metals were carried out at the Institute of Geochemistry and Physics of Minerals of the Academy of Sciences of the Ukrainian SSR (Kiev) by spectrographic analysis, and sulfur was determined by the volumetric chemical method at the NIIZh L and P USSR (Kharkov). In parallel, for comparison, the chemical composition of magnesium sulfate was determined as the closest to potassium magnesia by the chemical composition of the substance that is currently widely used as magnesium and sulfur-containing feed additives.

The data obtained by us in the analyzes on the comparative chemical composition of viburnum magnesia and magnesium sulfate are given in Table 1.

According to our chemical analyzes, the magnesium content in potassium magnesia is 5.3%, which is slightly lower than in magnesium sulfate (9%), and the sulfur content is 11.5%, i.e. the same amount as in magnesium sulfate,

It has been established that potassium magnesia contains macro- and microelements (sodium, calcium, iron, manganese, copper, molybdenum) in amounts not exceeding the permissible standards, biologically necessary for agricultural animals.

It was also established that potassium magnesia does not contain elements of heavy metals (lead, mouse, mercury, tin, cadmium, thallium and others), the accumulation of which in various organs and tissues of animals could cause their chronic or acute poisoning.

Consequently, the results of the emission of the full chemical composition of potassium magnesia indicate the possibility of its use as an accessible and safe magnesium-sulfur feed for animal health.

We also performed two scientific and economic experiments on the effect of feeding potassium magnesia on the meat productivity of cattle during rearing and fattening. The experiments were carried out on the collective farm Leninsky Shl x Obukhov district, Kiev region, on bull-calves analogous to black-motley breed by the group method.

The first experiment was carried out on 3 groups of bulls (13 goals each), of which I

the group was the control, II and III groups experienced.

The second experiment was carried out on 2 groups of calves (13 goals each), of which the first group was the control, the second was the experimental one.

The average weight of animals of 1 head when setting for the main period in the experiment is 327.6 - 334.6 kg, in the second experiment - 321.4 - 322.9.

In both experiments, the duration of the equalization period was 43 days, and the main one was 126 days.

The type of feeding experimental bulls in the experiments is silo-concentrate.

Feeding animals - normalized, group.

The diets were designed to receive 900 - 1000 g of gain in live weight per 1 head per day.

The experimental design and diets for feeding experimental bulls in the main period are presented in Table 2.

In the main period, bulls I (the control group in both experiments received the main diet (RR), consisting of compound feed, silage, chopped winter wheat straw, molasses and table salt.

According to the chemical analysis of feeds, the supply of control animals due to the main diet with magnesium and sulfur was respectively 85 and 80% of the currently recommended feeding standards.

In the main period of experiment I, in addition to the main diet, bulls of group II received 30 g, and bulls of group III received 60 g of potassium magnesia per head per day.

Due to the inclusion of potassium magnesia in the diets, the supply of gobies of the second and third groups of experiment I with magnesium was 92.2 and 99.5%, respectively, normal, which was higher than in the control by 8.6 and 17.1%.

The supply of bull calves of the second and third groups of experience with sulfur due to the inclusion of potassium magnesia in the diets was 90 and 100%, respectively, which was higher than in the control group by 12.5 and 25.0%.

In the main period of the second experiment, the bulls of the second (experimental) group received 90 g of potassium magnesia per head per day in addition to the main diet.

Due to the inclusion of potassium magnesia in the diets of gobies of the 2nd experiment, the provision of animals of the II (experimental) group with magnesium and sulfur was respectively 106.8 and 115.0 to the norm, which was higher than in animals of the control group by 25.7 and 43, 7%

At the end of the experiments, experimental animals were slaughtered at a meat processing plant with the determination of their slaughter yield of paired carcasses. In addition, in animals from each group of experiment 1, the chemical composition and qualitative indicators of meat (samples of the longest back muscle) were studied.

The feed costs for live weight gain in calves of the control and experimental groups were calculated, and the economic efficiency of using potassium magnesia as magnesium-sulfur feed for cattle fattening was determined.

The results obtained in the experiments are processed biometrically.

The performance indicators of experimental gobies I and II experiments are presented in table 3.

It was found that feeding calves of group II of the experiment of potassium magnesia at a dose of 30 g per head per day (with about 50% of the deficiency of magnesium and sulfur in the diet) increased their average daily gain in live weight by 72 g or 7.8% (difference statically not reliable, p 0.05).

When feeding gobies of group III of the experiment of potassium magnesia at a dose of 60 g per head per day (with 100% filling of the deficiency of magnesium and sulfur in diets, i.e. 15 and 20%, respectively), their average daily live weight gain increased in comparison with a control of 96 g, or 10.4% (the difference is statistically significant, p 0.05).

The inclusion of potassium magnesia in magnesium and sulfur-deficient diets increased the milk yield of paired carcasses of calves of groups II and III of experiment I to 50.1% from 49.5 in the control. Feeding gobies of the II experimental group II of the experiment of potassium magnesia at a dose of 90 g per 1 head per day, at which the supply of animal magnesium increased to 106.8%, and for sulfur - to 115.0% to normal, increased the average daily increase in their live weight against control 79 g or 8.6% (the difference is statistically unreliable. P 0.05), which is slightly lower than the increase in the average daily gain in animals of group III of the experiment when feeding them 60 g of potassium magnesia and their provision with magnesium and sulfur on level of 100% to normal.

When fed to calves of potassium magnesia at a dose of 90 g per head per day, the slaughter yield of their paired carcasses increased from 48.9% to 49.6%.

The chemical composition and qualitative characteristics of the meat of experimental gobies of the first experiment are presented in Table 4.

The studies did not establish a significant difference in the chemical composition and quality indicators

M ca in the gobies of the control and experimental groups.

Experimental studies on

The study of acute toxicity of potassium magnesium was carried out on black and white gobies

live weight rock about 200 kg by

periods.

As indicators characterizing the clinical condition of animals, temperature, pulse, and respiratory rate were taken into account. The content of calcium, phosphorus, magnesium, urea, sugar, citric acid, ammonia, was determined from the biochemical parameters in the blood of experimental gobies.

5 and also indicators of acid-base balance. These studies were carried out before feeding and after 1.3 and 6 hours after feeding: on the first day - without the use of potassium magnesia, on the second day - at

0 feeding potassium magnesia and on the third day - before feeding without the use of potassium magnesia.

The daily dose of potassium magnesia, which we use as toxic, amounted to 1 g per 1 kg of live weight of animals,

which is on average 5 times higher than its optimal

dose established in the scientific feeding experiments, i.e. 0.15 - 0.25 g

per 1 kg of live weight. The indicated dose of potassium magnesia was introduced into the rumen through the fistula in the form of a 10% solution.

As a result of experimental studies on the acute toxicity of potassium magnesia at the indicated dose, the absence of pronounced changes in the clinical status of animals according to the main indicators (temperature, pulse, respiration, palpitations, rumination, defecation, urination,

0 state of the nervous system, etc.).

The results of biochemical blood tests of experimental gobies when they feed toxic doses of potassium magnesia are given in table 5, and the indicators

5 acid-base balance of them in the blood in table.6.

As a result of biochemical studies, it was found that feeding animals potassium magnesia in

0 amount exceeding its optimal dose by about 5 times did not significantly affect the content in their blood of calcium, phosphorus, magnesium, urea, sugar, citric acid and ammonia, as well as

5, indicators of acid-base balance, which were in all studies within the physical norm. Therefore, a single injection of potassium magnesia into the rumen at a dose of 1 g per 1 kg of live weight does not have significant

changes in the clinical and biochemical status of animals.

When animals had free access to compound feed containing potassium magnesia, its maximum consumption was not more than 0.5 g per 1 kg of live weight, which eliminates their poisoning. Thus, potassium magnesia is a low-toxic product and can be used as a health-friendly animal magnesium-sulfur feed supplement.

The cost-effectiveness of potassium magnesia in cattle fattening is shown in Table 7.

It was found that the use of potassium magnesia as magnesium-sulfur feeding reduced feed costs for live weight gain in gobies of the second and third groups of experiment 1 by 7.9 and 10.1%, respectively, and in the gobies of group II of experiment I by 7.9 %

An additional gain in live weight per 1 kg of potassium magnesia in gobies of the II and III groups of the 1st experiment was 2.4 and 1.6 kg, and in the gobies of the II group of the II experiment - 0.9 kg. The cost of additional gain in live weight per 1 ruble for the use of potassium magnesia in gobies of the second and third groups of experiment 1 was 17.24 and 11.48 rubles, respectively, and for the gobies of group II of the second experiment - 6.3 rubles.

Therefore, the cost-effectiveness of potassium magnesia in cattle fattening as a magnesium-sulfur feed is very high, due to its low cost.

The economic effect due to the use of potassium magnesia instead of magnesium sulfate in the production of mineral-ammonia preparations, of which it is included, can be

Ukrainian SSR over 100 thousand rubles; the economic effect due to the use of potassium magnesia instead of magnesium sulfate as an independent top dressing is 400 thousand rubles, and only about 500 thousand rubles a year.

Thus, the results of the tests indicate the possibility of using potassium magnesia in

as an affordable cheap, harmless and highly effective magnesium-sulfur feed additive to increase cattle productivity when diets are deficient in

magnesium and sulfur. The optimal daily dose of potassium magnesia is 15 - 25 g per 100 kg of live weight of animals, depending on the deficiency of magnesium and sulfur in the diets.

The use of potassium magnesia as a feed additive for cattle has several advantages compared with the use of magnesium sulfate, since the proposed additive is more affordable for widespread use in animal husbandry, more than 3 times cheaper, which has a higher economic effect, expands assortment of magnesium - and sulfur-containing feed additives, which makes it possible to use scarce

and more expensive magnesium sulfate in other sectors of the national economy, which generally gives a significant economic effect,

FORMULA AND SECTION

A method of balancing cattle diets for magnesium and sulfur by introducing a mineral feed additive in them, characterized in that use is made of a mineral additive

potassium magnesia and take it in a dose of 0.15 - 0.25 g per 1 kg of live weight.

Table 1

Comparative chemical composition of potassium magnesia and magnesium sulfate,% by weight

Schemes of experiments and diets for feeding experimental gobies to the main

period

Continuation of table 1

Table 2

The performance indicators of experimental gobies I and II experiments

Table 3

Table 4

Biochemical blood parameters of experimental gobies in the study of acute toxicity

potassium magnesia

Baseline data without potassium magnesia (body status)

1 Before feeding, 8.43 +, 0.6 6.61 + 0.22 1, E ± 0.06 23.86 ± 1, E 58.24 + 1.7 4.7 + 0.09 0, l6tO, 06

2 After 3 hours after feeding 9.03 ± 0.48 6.510.17 1.7310.08 23.14 + 3.87 59.9913.75 4.8310.038 0.20310.037

3 After 6 hours. after feeding 9, 310.35 6.04tO, 22 1.83 + C. C7 & 1E, 22 ± 3.03 71.lS13.13 5,210,012 .. 0, .037 When feeding potassium magnesia

Before feeding 8, 9310.54 5.6110.23 1.6310.14 33.35i2.56 80,, 44 4.3 + 0.17 .0.18 + 1.012

1 hour after feeding 9.0310.31 6.44 + 0.21 1.83 ± 0.15 36, 71-77, 71 4.03 ± 0.11 (D, 16310.0037 3 hours after feeding 8 ,, 416.92 + 0.26 1.7710.37 34 .79 82.1511.82 4.3310.078 0.221.055

6 hours after feeding 8.33iO, 666,, 30 2.21 ± 0.16 29,, 42 83.911.92 4,, 078 0.17310.008

On the second day after feeding potassium magnesia Before feeding 9.57 + 0.31 5.0 S. DZ 2.7110.3 22.711.23.21 74.3110.31 3.610.12 0.15tO, 0058

h ..... v

Indicators of acid-base balance of blood of gobies in the study of acute,. toxicity of potassium magnesia

Table 5

Tableb

Table 7

Cost-effectiveness of potassium magnesia for fattening

cattle