RU2655739C1 - Method of use of amorphous hydrothermal nanosilica in poultry farming - Google Patents

Abstract

FIELD: agriculture.

SUBSTANCE: invention relates to agriculture, in particular to fodder production, and can find application in poultry farming. Essence of the invention is that the feed of chickens from their 10-day old age to their sexually mature age as well as of laying hens includes a sol, or a gel or a powder of amorphous hydrothermal nanosilica at a concentration of 0.0125–0.2 % in solid SiO₂ at a particle diameter of 5–100 nm.

EFFECT: implementation of the invention makes it possible to increase the efficiency of poultry growing when fattening chickens with a reduction in the timing of their fattening, to increase the egg productivity of laying hens, to reduce the waste of eggs in the production process, to improve the quality of eggs, to maintain the number of chickens in fattening and laying hens in the production of eggs.

1 cl, 5 tbl, 2 ex

Description

The invention relates to the field of agriculture, in particular to fodder production, and may find application in poultry farming.

Known mineral feed additive containing silica in zeolites, which in the amount of 3-5% are included in the diet of animals (patents No. 2151523 dated June 27, 2000, 2262863 dated October 27, 2005 and No. 2434530 on November 27, 2011).

A disadvantage of the known additives to the main diet is that, in addition to silicon, other substances contained in zeolites can also enter the poultry body. This leads to a decrease in the environmental safety of poultry products due to the content of carcinogenic impurities for a number of zeolite deposits.

The closest technical solution is a feed additive containing silica in the range of more than 80%. Opalkristobalite rocks (diatomite of a natural deposit) have a complex of minerals, which allows them to be used as a feed additive (patent No. 2197837 dated 02/10/2003. IPC A23K 1/16, A23K 1/175).

However, in the prototype, diatomite used as an additive does not provide high quality of the products obtained, since the silica compound is not completely accessible to the chicken body and penetrates the poultry body with all the chemical elements contained in diatomite. As a result, the productivity and egg laying of chickens is not sufficiently increased.

The technical result of the proposed solution is an increase in the efficiency of poultry rearing during the feeding of chickens with a reduction in the timing of their feeding, an increase in the egg productivity of laying hens, a decrease in egg waste during production, an increase in the quality of the egg, and the preservation of the number of chickens during feeding and laying hens in production.

The technical solution of the claimed object lies in the fact that, in contrast to the known, chickens from 10 days old to their adult age and laying hens include sol, or gel, or amorphous hydrothermal nanosilica powder at a concentration of 0.0125-0.2 % solid SiO ₂ with a particle diameter of 10-100 nm.

The method is as follows.

A hydrothermal nanosilica sol is obtained by ultrafiltration concentration (purification from impurities) of thermal waters from a depth of 500-3000 m of the Mutnovsky steam-hydrotherm field (Kamchatka). Nanosilica sols had a concentration of 10.0% or more on solid amorphous SiO ₂ , particle diameters SiO ₂ 5-100 nm.

The gel form of hydrothermal nanosilica was obtained by changing the temperature and pH of aqueous sols of nanosilica and their transition from the form of sol to gel. The gel form of nanosilica has been tested many times on many living objects (plants, protozoa, insects, daphnia crustaceans, laboratory animals) and has shown its safety and environmental safety.

Nanosilica powder was obtained by freeze-drying in a vacuum frozen granules of sol or gel through their dispersion into a cryogenic liquid (cryogranulation).

Silicon, which is part of the organic components of cells, actively affects their metabolism and takes part in the physiological processes of living organisms of different organizations. Silicon deficiency in the body delays the growth and development of living organisms, which leads to a decrease in their productivity and resistance to adverse environmental conditions.

The lack of silicon in the diet of chickens negatively affects their livelihoods, being a risk factor contributing to the onset of diseases and a decrease in their meat productivity, egg production and egg quality indicators.

In the proposed method, a sol, or gel, or hydrothermal nanosilica powder is dosed to feed chickens, repair young animals, laying hens in a certain amount, calculated on solid SiO ₂ relative to the feed.

According to x-ray phase analysis, the substance of the particles of SiO ₂ has an amorphous structure.

The justification of the selected method parameters for doses of hydrothermal nanosilica in concentrations of 0.0125-0.2 wt.% (Or 0.125-2.0 g per 1 kg of feed) for solid amorphous nanosilica and a diameter of 5-100 nm in the feed is proved by experimental data obtained for chickens of the egg-meat direction of the Highsex Brown breed according to generally accepted methods for conducting experiments on feeding poultry. At the same time, various forms of amorphous hydrothermal nanosilica in 3 versions (sol, gel, powder) were added to the main diet, balanced according to the main nutrients for poultry (metabolic energy, calcium, phosphorus, crude protein, fiber, essential amino acids) their content in 1 kg of feed for chickens and adult birds (laying hens) in quantities of 0.125 g, 0.25 g, 0.5 g, 1.0 g, 1.5 g and 2.0 g, calculated on solid SiO ₂ (silicon dioxide) as the basis of various forms of nanosilica. This size of nanoparticles (5-100 nm) contributes to the rapid dissolution and assimilation of the bird by the body.

Example 1. Tests of amorphous hydrothermal nanosilica as an additive in feed during the cultivation of chickens before maturity (period of egg production).

For the experiment, 10 groups of hatched chickens of industrial birds were formed: one - control and nine - experimental, 90 goals in each group. The control group received the main diet of a balanced feed.

Experienced 9 groups received the main feed with 1 kg of it introduced while stirring the following amounts of the tested variants of amorphous hydrothermal nanosilica additives:

- 10 ml, 15 ml and 20 ml of 10% sol of nanosilica, which corresponds to the content on the basis of solid SiO ₂ 1.0 g, 1.5 g, 2.0 g per 1 kg of feed or percentage concentration in feed on solid SiO ₂ in 0.10%, 0.15%, 0.20%, respectively, for the 1st, 2nd and 3rd experimental groups;

- 10 g, 15 g and 20 g of 10% nanosilica gel, which corresponds to the content on the basis of solid SiO ₂ 1.0 g, 1.5 g, 2.0 g in 1 kg of feed or the percentage concentration of solid SiO ₂ in 0.10%, 0.15%, 0.20%, respectively, for the 4th, 5th and 6th experimental groups;

- 1.0 g, 1.5 g and 2.0 g of hydrothermal nanosilica powder, which corresponds to the content based on solid SiO ₂ 1.0 g, 1.5 g, 2.0 g in 1 kg of feed or percentage concentration solid SiO ₂ in 0.10%, 0.15%, 0.20%, respectively, for the 7th, 8th and 9th experimental groups.

The duration of the experiment was 150 days. Beginning of feeding - 10 days after hatching chickens.

Tables 1-3 show the average daily gain in grams for chickens in the control and experimental groups. The gain indicators are given as averaged data for 90 chickens for each group in different age periods during their feeding.

As can be seen from table 1, the use of hydrothermal nanosilica sol for all experimental groups and different age groups of chickens increases their average daily gain during fattening with a maximum gain of 9.7% relative to the control for the 3rd experimental group of 150-day-old youngsters.

The use of hydrothermal nanosilica in the form of a gel as an additive in food for all experimental groups and different age groups of chickens increases their average daily gain during fattening with a maximum value of 4.7% relative to the control for the 6th experimental group of 150-day-old youngsters (table 2).

The use of hydrothermal silica in the form of a powder as an additive in food for all experimental groups and different age groups of chickens increases their average daily gain during fattening with a maximum value of 4.9% relative to the control for the 7th experimental group of 60-day-old chickens (table 3).

Egg production for young chickens in groups supplemented with hydrothermal nanosilica in the feed appeared earlier (at the age of 4.3 months) compared to the control (at the age of 5.0 months), which increases the efficiency of raising a bird to puberty by 14% when using poultry as as layers, and for the meat industry. This reduces costs corresponding to 21 days of keeping the chickens and their feeding until adulthood.

Example 2. Tests of hydrothermal nanosilica as additives in the feed of laying hens

Feeding was performed on laying hens of the egg-meat direction of the Highsex Brown breed using generally accepted methodological guidelines for conducting experiments on feeding poultry.

The birds were weighed on an electronic balance.

For the experiment, 10 groups of adult hens were formed, one - control and nine - experimental, 70 animals in each group. The control group received the main diet, and the experimental groups received, together with the feed, hydrothermal nanosilica in the form of 10% gel in doses of 1.25 g, 2.5 g, 5.0 g, 10 g, 15 g, 20 grams per 1 kg of feed: 1st, 2nd, 3rd, 4th, 5th and 6th - experimental groups, respectively (table 4) and amorphous hydrothermal nanosilica powder in an amount of 1.0, 1.5, 2.0 grams per 1 kg of feed: 7th, 8th, 9th experimental groups, respectively (table 5).

The age of chickens when tested is 150 days. The duration of the experiment is 150 days.

The diet and light conditions of the control and experimental chickens were the same. The diet for feeding a variety of feeds was varied, nutritional value met the requirements of the All-Russian Scientific Research and Technological Institute of Poultry (VNITIP).

In the experiment, we took into account: egg production (daily) by taking into account the number of laid eggs by groups, egg mass (by group weighing for five days).

As can be seen from tables 4 and 5, for all experimental groups of laying hens, both the gross egg laying in groups and the average laying egg per hen exceed the indices of the control group.

* Note: the concentration of hydrothermal nanosilica in the feed for experimental 1st, 2nd, 3rd, 4th, 5th, 6th groups of laying hens was 0.0125%, 0.025%, 0.05% , 0.1%, 0.15%, 0.2% relative to solid SiO _2, respectively.

* Note: the concentration of hydrothermal nanosilica in the feed for experimental 7th, 8th, 9th groups of laying hens was 0.1%, 0.15%, 0.2% relative to solid SiO _2, respectively.

For the studied 150-day period, the highest productivity was in the sixth and ninth experimental groups. Compared to the control group, in the sixth group there are 594 more eggs, which is 8.5 eggs per average layer or 7.4% more than in the control, and in the ninth group, 636 eggs more than in the control, which is 9 , 1 eggs per medium layer, or 7.9% more control.

The control group had the lowest egg productivity. In all tested ranges of concentrations of amorphous hydrothermal nanosilica and its use in the form of a gel (table 4) and powder (table 5) in poultry feed, the average egg production in pieces / head and in kg / head per hen per 150 days exceeded the similar average values for 70 hens for the control group. In this case, the egg mass increases by 1.2 g (up to 1.7%) (table 4, experimental group 3) and the shell thickness increases to 5.7% (table 4, experimental group 6). As a result, with an improvement in the quality of the egg, its output in the production process decreases to 6.4% (table 4, experimental groups 2 and 4).

The safety of birds in all experimental groups was 100% and in the control group 98.6%.

The live weight of young chickens at 150 days of age was within the standard for a given cross of poultry.

As a result of the tests, experimental data were obtained on the positive effect of the feed additive of amorphous hydrothermal nanosilica in various forms of its application, which makes it possible to increase the safety of poultry by 1.4% and increase its egg production to 7.9% (tables 4, 5) with an increase in egg quality by weight by 1.7% and by shell thickness by 5.7%, with a decrease in egg battle during production by 6.4%.

Based on the data obtained, it can be concluded that when using a feed additive in the form of sol, gel and amorphous hydrothermal nanosilica powder, when used in concentrations of 0.0125% -0.2% on solid SiO ₂ , the safety of the number of chickens increases when growing egg-meat poultry directions, their average daily gain and reduced feeding time before the laying of eggs (technical maturity).

For mature laying hens, along with an increase in the egg laying capacity of the bird and the safety of the livestock, the quality of the egg in terms of weight and thickness of the shell increases with a decrease in egg battle during production.

The feed additive is not toxic to plants, protozoa and higher animals.

The method allows to increase the efficiency of poultry rearing during the feeding of chickens with a reduction in the timing of their feeding, to increase the egg productivity of laying hens, to reduce egg waste during production, to improve egg quality, to preserve the number of chickens during feeding and laying hens in egg production.

Claims (1)

The method of using amorphous hydrothermal nanosilica as a feed additive, characterized in that the chickens from 10 days of age to their adult maturity and laying hens include sol, gel or amorphous hydrothermal nanosilica in a concentration of 0.0125-0.2 % solid SiO ₂ with a particle diameter of 5-100 nm.