RU2711259C1 - Method for preparation of fodder additive for young cattle - Google Patents

Abstract

FIELD: agriculture.SUBSTANCE: invention relates to agriculture, in particular to a method for preparation of a fodder additive for young cattle. Method involves introduction of additional fertilizer into the main ration of calves. Calves aged 6–7 months by mixing with concentrated milled grain fodder are added ultrafine CrOchromium nanoparticles sized 91 nm in dose of 1.4 mg per head once a day for a recording period of 7 days.EFFECT: use of the invention enables higher activity of pancreatic enzymes: amylase and protease.1 cl, 2 tbl

Description

The invention relates to the field of agriculture and can be used to increase the productivity of farm animals (in particular calves).

One of the essential minerals for animals is chromium, it is found in all organs and tissues, stimulates the growth and development of animals, participates in osteogenesis, metabolism of proteins, carbohydrates, fats, blood formation processes, interacts with enzymes, hormones, nucleic acids and vitamins [1 -5]. However, at present, there is very little information in the literature about the chromium content in animal feed, namely, the rate of introduction into the diet of animals.

Based on the results of studies by some authors, it was noted that chromium plays a huge role in the cultivation and nutrition of farm animals. So, in [6], it was noted that when chromium is introduced into sows, an improvement in mineral and protein metabolism is noted. The use of mixed fodder with chrome yeast had a positive effect on the productivity of sows and young animals, allowed to obtain an additional 0.8 piglets per sow, the average daily growth of piglets after the weaning period increased by 5.3% while reducing the cost of exchange energy by 5.24% [6].

The additional inclusion of chromium in the diet of dairy cows has a positive effect on the digestive processes and helps to increase the digestibility of dry and organic matter, crude protein, fat, fiber and BEV, the use of nitrogen, calcium, phosphorus and chromium. Optimization of chromium in the diets of dairy cows contributes to an increase in milk productivity, an improvement in the chemical composition and an increase in the quality of milk [7].

The inclusion of chromium in the diet of dairy cows improves the state of health, increases the metabolism in the body, as evidenced by the high content of red blood cells, hemoglobin, total protein and its fractions, total calcium and inorganic phosphorus in the blood [7].

Chang and Mowat (1992) investigated the effects of high chromium yeast in young cattle. During the first 28 days of the experiment, the average daily weight gain increased by 30%, and feed efficiency by 27% [8].

Tests with the addition of chromium to the diet of fattening pigs showed that the effect on daily weight gain was dependent on the dose of chromium [9].

Earlier in [10], it was shown that when the chromium preparation was added to the diet of animals (rats), the live weight of animals in the experimental (receiving various doses of UD chromium preparations) and control groups changed slightly [10].

A known method of feeding farm animals, comprising introducing magnesium compounds, such as magnesium oxide or magnesium sulfate, in an amount of 15-20 g and 25-30 g, respectively, per head per day, into the main diet, and magnesium oxide or sulfate is administered once per day daily for 40 days, calves in the period of growing. The invention allows to increase metabolic processes in calves, namely, it increases the activity of pancreatic enzymes. The disadvantage of this method is its high cost [12].

There is a method of introducing inorganic chromium buffalo to the calves in a dosage of 0.5; 1.0 and 1.5 mg per kg of dry matter of the feed, which did not affect the consumption of nutrients and growth rates [14].

The objective of the proposed method is to determine the effective optimal stimulating dosage of chromium in the diet of calves, but in the form of nanoparticles (NPs), which have more effective properties on the body than inorganic chromium [15, 16].

The essence of our proposed method is to increase the enzymatic activity of the pancreas of calves by introducing chromium NP into the diet, which increases the metabolic processes of the body, including increasing the activity of pancreatic enzymes, lowering cholesterol, total protein and aminotransferases.

The calf feeding rate at 6–7 months of age was calculated from the nutritional value of the diet for dry matter at 3.7–4.4 [13].

The task is achieved by the fact that ultrafine particles of chromium 91 nm in size in the amount of 0.3 mg per kg of dry matter of the nutritional value of the diet are introduced into the main diet for calves aged 6-7 months by mixing with a concentrated mixture of the diet once a day, or 0.3 × 4.2 = 1.26 mg per head plus 10%, taking into account eatability and loss, i.e. 1.4 mg / goal, while administered daily for 7 accounting days.

The object of the study was calves aged 6-7 months. They, according to the principle of analogue pairs, were formed into four groups of 5 goals each. The homogeneity of the animals in the experimental groups was carried out by selecting analogues for such indicators as physical condition, live weight, age. All animals had average fatness and were clinically healthy. During the experiment, the calves were in the same conditions of feeding and keeping. Feeding experimental animals was organized taking into account the recommendations of A.P. Kalashnikov et al. [4, 13].

All groups with calves during the first 7 days were in the preparatory period and received the main diet, which in nutritional value per 1 kg of dry matter was 4.2 kg / goal [13].

For the study, ultrafine chromium particles obtained by the method of plasma chemical synthesis were used (Platina LLC, Moscow). The preparations Cr ₂ O ₃ NP (d = 91 nm, specific surface area 9 m ² / g, Z-potential 93 ± 0.52 mV) contained 99.8% Cr. Before being included in the diet, ultrafine chromium particles were dispersed in physiological saline using USN-2T (NPP Akadembribor, Russia) (35 kHz, 300 W, 10 μA, 30 min). Cr ₂ O ₃ was introduced into the compound feed by kneading with a concentrated diet mixture: the experimental group at a dose of 0.1 mg per kg of dry matter of nutrient intake once a day or 0.1 × 4.2 = 0.42 mg per head plus 10% taking into account eatability and losses, i.e. 0.46 mg / goal, the experimental group at a dose of 0.2 mg × 4.2 = 0.84 mg per head plus 10%, i.e. 0.92 mg / goal and the experimental group III, 1.4 mg / goal, respectively, the control group received the main diet [11].

The experiment was performed in accordance with the protocols of the Geneva Convention and the principles of good practice (National Standard of the Russian Federation GOST R 534342009), as well as with the instructions “The Guide for the Care and Use of Laboratory Animals (National Academy Press Washington, D.C. 1996).”

At the end of the experiment, samples of pancreatic juice were taken, due to the original operation for applying a duodenal anastomosis according to the method developed by A.D. Sineshchekov [11].

The results obtained during the experiment were statistically processed using the Statistica 10.0 software package. The significance of differences in the compared indicators was determined by the t-student criterion. The level of significant difference was set at p≤0.05.

As a result of the experiment, it was noted that at the end of the 7 day reference period, there was a significant increase in amylase activity in the III experimental group by 33.2% (p≤0.05) and protease by 25.4% (p≤0.05), respectively, relative to the control group. An increase in the activity of pancreatic enzymes was observed in the I and II experimental groups, however, the changes were unreliable (Table 1).

Considering biochemical parameters (Table 2), the effect of NP Cr ₂ O ₃ on the calf’s organism was manifested in the established hyperglycemic effect, expressed in an increase in glucose by 0.6% in the experimental group I, by 1.36% in the II group and by 10, 6% in the III experimental group compared with the control.

Triglycerides, as true fats, significantly increased in the III experimental group by 14.3% (p≤0.05), relative to the control group, which indicates the effect of chromium on lipid metabolism, causing the breakdown of excess fat in the body, which is confirmed by studies [10 ].

At the same time, the additional inclusion of chromium NPs in the compound feed at a dose of 1.4 mg / goal (experimental group III) led to a depressed protein metabolism, expressed in its significant decrease by 9.6% (p≤0.05).

The data on the content of Fe in the blood are interesting: if, at low levels, chromium and iron predominantly occupy different binding sites [9], then at higher levels, they compete for these sites, which manifests itself in a decrease in iron metabolism in the experimental groups.

Analysis of the reaction of aminotrasferases, as an indicator of the presence of damage in the cells, established a decrease in the activity of ACaT and ALaT in the III experimental group of 10.4% and 7.9% (p≤0.05), respectively. Triglycerides, like true fats, increased by 14.3%, which indicates the effect of chromium on lipid metabolism, causing the breakdown of excess fat in the body, which is confirmed by studies [5]. In the III experimental group, there was a significant decrease in cholesterol by 1.2 times (p≤0.05).

A decrease in the activity of aminotransferases, on the one hand, may indicate the absence of toxic effects of chromium nanoparticles on the body, and on the other, a violation of the protein synthesizing function of the liver, as evidenced by a decrease in the protein level in the blood plasma of calves of the experimental group III. At the same time, the activity of protease and amylase in the duodenal chyme increased, due to the possible inclusion of adaptation mechanisms to maintain homeostasis of lipid and protein metabolism [9].

Thus, from the data obtained it follows that the best effect of increasing the activity of pancreatic enzymes was observed in calves when they were supplemented with ultrafine particles of chromium at a dose of 1.4 mg / goal, which increased the level of activity of calf enzymes: amylase by 33.2%, proteases by 25.4%, compared with the control.

Sources of information

1. Bolotin E.V. The productivity of full-aged cows at different levels of chromium in their diets: abstract. dis. ... cand. S.-kh. sciences / E.V. Bolotin. - Saransk, 2012 .-- 23 p.

2. Georgievsky, V.I. Mineral nutrition of animals / V.I. Georgievsky, B.N. Annenkov, V.T. Samokhin. - M .: Kolos, 1779 .-- 470 s.

3. Gibalkina, N.I. The need for bull calves in chrome with hay feeding type: abstract dis. ... cand. S.-kh. sciences / N.I. Gibalkin. - Saransk, 1998 - 25 p.

4. Kalashnikov, A.P. Norms and rations for feeding farm animals / A.P. Kalashnikov, V.V. Shcheglov, N.I. Kleimenov. - M., 2003 .-- 422 p.

5. Kokorev, V.A. Optimization of the mineral nutrition of farm animals / V.A. Kokorev, A.M. Guryanov, N.I. Gibalkina // Zootechnics. - 2004. - No. 7 - S. 12-16

6. Lobkov V.Yu., Frolov A.I. Biochrom as part of pig feed. - No. 3 (43), 2018 S. 5

7. Kokorev, V.A. The productivity of full-aged cows at different levels of chromium in their diets / V.A. Kokorev, E.V. Bolotin, N.I. Gibalkina, A.N. Fedaev, A.M. Guryanov / Livestock and veterinary medicine, No. 2, 2017 - P. 20-30

8. Chang X, Mowat DN. 1992. Auxiliary chrome for stressful and growing farm birds. J. Anim. Sci. 70: 559-65

9. Southern LL, Ward TL, Thomp-son DL. 1993. The effect of chromium picolinate on the growth and development of pigs. J. Anim. Sci. 71: 656-62

10. Sheida E.V., Lebedev S.V., Gavrish I.A., Gubaidullina E.Z. In the collection: Beef cattle breeding - priorities and development prospects materials of the international scientific-practical conference. Under the general editorship of Miroshnikov S.A. 2018.P. 165-167.

11. Sineshchekov A.D. Food processes and their nervous regulation in farm animals // Abstracts of the VIII All-Union Congress of Physiologists, Biochemists, Pharmacologists. - 1955. - 736 p.

12. Patent for invention No. 2615151 publ. 04/20/2001, BI No. 10 "Method for feeding farm animals." Scheglov E.V., Zaplatnikova G.M., Novikova N.N.

13. Kalashnikov AP, Fisinin V.I. et al. Norms and rations for feeding farm animals. Reference manual 3rd edition revised and expanded, - Moscow. 2003 .-- 456 p.

14. Kumar M., Kaur N., Deka RS, Mani V., Tyagi A.K., Chandra G. Dietary Inorganic Chromium in Summer-Exposed Buffalo Calves (Bubalus bubalis): Effects on Biomarkers of Heat Stress, Immune Status, and Endocrine Variablss. - Biological Trace Element Research, 167 (1), 2015, P. 18-27.

15. Nesterov D.V. The effect of finely divided metal powders on metabolism and animal productivity against the background of enzyme-containing diets: abstract. diss. Cand. biol. sciences. - Orenburg, 2009 .-- 22 p.

16. Nazarova A.A. The influence of nanopowders of iron, cobalt and copper on the physiological state of young cattle: Ph.D. thesis. biol. Sciences: 03.00.13 - physiology. - Ryazan, 2009 .-- 137 s.

Note: * - the results are statistically significant (p≤0,05)

Note: * - the results are statistically significant (p≤0,05)

Claims (1)

A method of feeding young cattle, characterized in that the calves at the age of 6-7 months are injected with concentrated crushed grain feed with ultrafine 91 nm chromium Cr ₂ O ₃ nanoparticles in a dose of 1.4 mg per head once a day for 7 days .