RU2751961C1 - Method for increasing the digestibility of nutritional components of feed when including ultrafine chromium oxide particles in diet of cattle - Google Patents

Abstract

FIELD: agriculture, cattle farming in particular.

SUBSTANCE: invention relates to agriculture, in particular to the industry of beef cattle breeding to improve the productive qualities of young cattle. A method for increasing the digestibility of the nutritional components of the feed of young cattle is proposed, in which the diet of calves of 8 months of age includes a protein component in the form of soy meal with the inclusion of ultrafine Cr₂O₃ particles of 91 nm in size at a dosage of 200 mcg/kg of live animal weight once a day during the growing period of 14 days.

EFFECT: invention contributes to increased stimulation of the digestibility of nutrients in the protein diet, namely, it makes it possible to increase the digestibility of organic matter by 9.6%, crude protein by 2.7%, crude fat by 13.8%, crude fiber by 5.2%, contributing to increased live weight of calves by 7%.

1 cl, 1 dwg, 1 tbl

Description

The invention relates to agriculture and can be used in the livestock industry for meat production to increase the productivity of farm animals (in particular young cattle).

For the production of high quality food products in beef cattle breeding, much attention is paid to the preparation of feed and the creation of components of diets that are diverse in terms of quantitative and qualitative composition. However, the load of rations with additional components can adversely affect the state of the digestive system in particular and the body as a whole, and lead to a decrease in the digestibility of nutrient components of the feed and their bioavailability, and, as a consequence, to a decrease in productivity. To solve this problem, it is necessary to include additional substances, in the form of additives of mineral components, as modulators that increase the availability of nutrient components of the feed.

One of the vital (essential) elements is chromium. Chromium plays a key role in carbohydrate, protein and lipid metabolism, as well as in improving immune function. The organic source of chromium has been found to be highly bioavailable, and the beneficial effects of supplements have been proven by various studies in animal husbandry. The addition of chromium alleviates the negative effects of stress, thereby improving the productivity and health of livestock, which leads to an increase in the profitability of production [1]. It maintains normal blood glucose levels, enhances the action of insulin, ensures the structural integrity of nucleic acids, regulates the thyroid gland and the activity of the heart muscle, enhances regeneration processes, and promotes the elimination of toxic elements from the body [2, 3].

The main role of chromium in metabolism is to enhance the uptake of glucose by cells. Chromium also activates some enzymes and stabilizes proteins and nucleic acids [3, 4].

With a chromium deficiency in animals, the ability to incorporate 4 amino acids (glycine, serine, methionine and γ-aminobutyric acid) into the heart muscle is impaired. In addition, a lack of chromium leads to growth retardation, causes neuropathies and impaired higher nervous activity, and reduces the fertilizing capacity of sperm [4, 5].

An important tool in the regulation of the exchange of incoming chromium in the body is its ability to penetrate the intestinal wall. The efficiency of chromium absorption depends on the size of its molecule and the presence of digestive agents (vitamins, phytates, amino acids) [6].

The addition of chromium to the diet of calves in feedlots led to an increase in the growth rate, feeding efficiency, humoral immune responses and a decrease in morbidity compared to control calves without additives. It has been shown that the addition of chromium to forage calves subjected to transport stress improves growth performance during the first few weeks after arrival. In contrast, when physiologically adapted calves were fed for longer feeding periods, growth performance was not affected by chromium supplementation [1, 2].

Studies in Canada have confirmed the need to add chromium to ruminant feed. In the study, 108 calves fed corn silage supplemented with high chromium yeast gained 30% more than control animals in the first 28 days after feeding. The role of chromium is mainly to increase the effectiveness of insulin action. It is well known that the body's need for chromium increases during stressful conditions, and it has been established that chromium supplementation protects against the loss of a number of trace elements during stress. The addition of chromium to the feed of highly productive dairy cows is especially necessary [7].

The addition of chromium reduces the negative effects of environmental stress. Additional dietary chromium is recommended for animals exposed to environmental stress [2, 5, 8].

It has been observed that chromium supplementation tends to increase dry matter intake in cows during the first 4-6 weeks postpartum. Dairy cattle provided chromium as chromium propionate, consumed more feed and produced more milk than cows that did not receive chromium. Increasing milk production can be an indirect effect of increasing glucose production. Additional organic chromium increased milk yield by 11% during the first 14 weeks of lactation in first parity cows [9, 10].

Research carried out by world science now confirms the assumption about the positive effect of the introduction of chromium nanoparticles on the animal organism and its biogenic character, especially under conditions of technological stresses and deficiency in feed [11].

Metal nanoparticles have unique properties and can be used to treat the body of animals, stimulate the growth of plants and animals, as new feed ingredients or additives, improve the absorption and bioavailability of nutrients, improve the safety and quality control of feed and animal products [12, 13].

The use of chromium nanoparticles in the diets of young cattle of experimental groups in the amount of 0.050 and 0.075 mg per 1 kg of dry matter of the diet, contributes to an increase in average daily gains by 6.6-3.3%, a decrease in the cost of products obtained by 4.9-1.4 % and additional profit in the amount of 18.0-4.9 rubles per head, respectively [14].

It was found that chromium nanoparticles do not have a toxic effect and have a versatile effect on hematological parameters and metabolism in the body of calves, which is reflected in a decrease in protein and stimulation of carbohydrate and lipid metabolism. The addition of Cr to the diet of calves is accompanied by an increase in glucose concentration by 10.6% (P≤0.05), triglycerides - by 14.3%, against the background of a decrease in cholesterol by 16.9% [15].

A known method of feeding young cattle, including the introduction into the diet of calves 6-7 months of age of ultrafine particles (UF) of chromium Cr ₂ O ₃ . The use of this invention makes it possible to increase the level of activity of pancreatic enzymes [16].

The essence of the proposed method is to increase the digestibility of nutritional components of rations in feeding young cattle by introducing into protein-containing rations, with the inclusion of soybean meal as a protein component, UDC Cr ₂ O ₃ , which contributes to an increase in the gain in live weight of calves.

_{The task is achieved by the fact that ultrafine particles of Cr 2} O ₃ are introduced into the diet containing soybean meal by mixing with a concentrated mixture, calculated on the live weight of the animal's body: I experimental group at a dosage of 100 μg / kg, II experimental group at a dosage 200 mcg / kg and III experimental group 300 mcg / kg.

To study used particle UDCH chromium Cr ₂ O ₃ (d = 91 nm, specific surface - 9 m ² / g, Z-potential of - 93 mV ± 0,53) containing 99.8% Cr were prepared by plasma chemical synthesis (OOO " Platinum ", Moscow). Before being included in the diet, the nanoparticles were dispersed in saline using an UZDN-2 ultrasonic disperser (NLP Akadempribor, Russia) (35 kHz, 300 W, 10 μA, 30 min).

The object of the study was calves at the age of 8 months weighing 223-224 kg. According to the principle of analogous pairs, they were formed into four groups of 4 heads each. The homogeneity of the animals of the experimental groups was carried out by selecting analogs according to such indicators as physical condition, live weight, age. All animals were of average body condition and were clinically healthy. During the experiment, the calves were kept in the same feeding and housing conditions. The feeding rate of calves at 8 months of age is calculated from the nutritional value of the diet on dry matter in 5.4-5.6 kg. The feeding of the experimental animals was organized taking into account the recommendations of A.P. Kalashnikov and others [17].

The experiment was carried out in duplicate using the Latin square 4 × 4 in the laboratory of biological tests and examinations of the Federal Scientific Center for Biological Systems and Agricultural Technologies of the Russian Academy of Sciences.

The animals were kept in separate metabolic cages (1.0 × 2.2 m) in a room with optimal temperature and humidity parameters for a given animal species with free access to water. During the experimental period, the ambient temperature was maintained between 23 ° C and 25 ° C.

Animal care and experimental studies were performed in accordance with the instructions and recommendations of Russian Regulations, 1987 (Order No. 755 on 08/12/1977 the USSR Ministry of Health) and “The Guide for Care and Use of Laboratory Animals (National Academy Press Washington, DC 1996) ".

Laboratory research was carried out in the laboratory "Nanotechnology in Agriculture" and the Testing Center (Federal Research Center "Biological Systems and Agrotechnologies of the Russian Academy of Sciences", accreditation certificate RA.RU.21PF59 dated 02.12.15).

The digestibility of the feed was assessed for 7 days in the course of carrying out the balance experiments and the amount of feed consumed by the animals, uneaten residues, and the amount of excreted feces were taken into account. The digestibility coefficient (CP) was calculated in% as the ratio of the digested nutrients to the accepted nutrients. In feces and feeds after freezing, drying, homogenization, the content of nutrients was analyzed: dry matter, crude protein, crude fat and ash content in accordance with the recommendations of the AOAC (1995). Digestibility was assessed according to Hashemi S.R. et al. [18].

Accounting for changes in live weight of animals was carried out in the period from 8 to 12 months of age once a month by individual weighing.

The results obtained during the experiment were statistically processed using the Statistica 10.0 software package. The significance of the differences between the compared indicators was determined by the Student's t-test. The level of significant difference was set at p≤0.05.

Analysis of the data showed that when the protein component (soybean meal) was included in the diet, the digestibility of dry matter by 11.2%, organic matter by 28.2% (p≤0.05), crude fat by 25.7% (p≤0.05), BEV by 19.8% and crude fiber by 7.1%.

With the additional inclusion in the diet containing soybean meal, UDC Cr ₂ O ₃ in various dosages, an increase in the digestibility of dry matter was noted by 13.1% in group II, by 15.6% in group III and by 12.1% in group IV relative to this indicator in group I. An increase in the digestibility of organic matter, crude fat, crude protein and BEV was also noted; these coefficients were higher in the III experimental group. Compared to the control values, the digestibility of the nutritional components of the diet increased in all experimental groups (Table 1).

Additionally, the inclusion of Cr ₂ O ₃ UDC in diets in various dosages has a different effect on the formation of live body weight in experimental bulls (Figure 1). The staged live weight of young animals of all groups was practically the same and averaged 223.5-224.0 kg. By the end of the registration period, the live weight in the control and experimental groups increased unevenly: by the age of 12 months, the maximum live weight increased in the group receiving UDC of chromium oxide at a dosage of 200 μg / kg of live weight per day and amounted to 346.6 kg. The increase in live weight over the reference period of 5 months in the experimental groups relative to the control was higher in group I by 3.7%, in group II by 3.6%, in group III by 4.7%, in group IV by 7%.

Thus, the inclusion of UDC Cr ₂ O ₃ against the background of feeding a protein diet, helps to increase the stimulation of the digestibility of nutrients in the diet - dry matter, organic matter, crude protein, crude fat and BEV and, as a consequence, an increase in the increase in live weight of animals. The best effect of the studied indicators was observed in animals that received UDC Cr ₂ O ₃ against the background of feeding a protein-containing diet (with the inclusion of soybean meal), at a dosage of 200 μg / kg of live weight per day, therefore, the use of this feeding when raising young cattle is an effective way increasing the digestibility of nutrient components of the feed.

Sources of information

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Claims (1)

A method for increasing the digestibility of nutritional components of young cattle feed, characterized by the fact that the diet of 8-month-old calves includes a protein component in the form of soybean meal with the inclusion of ultrafine particles of Cr ₂ O ₃ 91 nm in size at a dosage of 200 μg / kg of animal live weight once per day during the growing period of 14 days.

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