RU2662905C1 - Method for predicting individual growth rates of young sheep - Google Patents

Abstract

FIELD: agriculture.SUBSTANCE: invention relates to agriculture and can be used to predict individual growth rates of young sheep. Bioelectric potential is measured on any part of the sheep's body with a single electrode. If the bioelectric potential is from 2.5 to 10 mV, intensive growth is predicted. If the bioelectric potential is from 20 to 60 mV, slow growth is predicted. Bioelectric potential of 10 to 20 mV corresponds to the transition period from intensive to slow growth or from slow to intensive growth.EFFECT: method provides increased efficiency and accuracy of determining the rates and nature of growth of farm animals in accordance with the biological characteristics of a particular animal by measuring the objective bioelectric index.1 cl, 22 dwg, 1 tbl, 4 ex

Description

FIELD OF THE INVENTION

The invention relates to agriculture, in particular to a method for determining the individual growth rate of young sheep, and can be used in breeding, breeding and veterinary medicine of farm animals.

State of the art

A known method of accounting and characteristics of the growth of animals, based on measurements of fixation of linear dimensions, surface, volume, weight, height of animals (see Liskun EF Exterior of farm animals, M., 1949).

The disadvantages of this method are: partial measurements of body parameters that do not reflect the overall growth and development of the animal; the impossibility of accurately determining the body volume due to its unstable density and mass, the specific metabolism of the body, and the operational accounting of the individual's waste products.

There is a method of evaluating animal growth by studying submicroscopic structures — macromolecules and molecules, based on the use of Zeiten scales (see Setlow R., Pollard E. Molecular Biophysics. M., Mir, 1964).

The disadvantages of this method are: the need for special laboratory equipment; the mismatch between the characteristics of the cell, molecule and the state of the whole organism of the animal.

A known method of determining the growth rate of an animal, based on the mathematical processing of empirical data of measurements of animals (see Chirvinsky N.P. Selected Works, vol. 1, M., 1949; Plokhinsky N.A. Biometrics, Novosibirsk, 1961) .

The disadvantages of this method are: the need for a large amount of source data for a reliable assessment of the results; the high complexity of collecting animal measurements.

A known method of measuring the electromagnetic radiation of an organism of farm animals by a device for measuring the electromagnetic radiation of an organism of farm animals, comprising an electrode connected through a first resistor to an amplifier, which consists of two silicon transistors of reverse conductivity, a bridge formed by three resistors and a potentiometer, a microammeter and a constant power supply current, while the electrode is made in the form of a sensor sensor with the possibility of eliminating the influence of elec resistance of the body of a living organism, while the sensor is connected to the first output of the first resistor, the second output of which is connected to the base of the first transistor, the emitter of which is connected to the base of the second transistor, the emitter of the second is connected to the first output of the second resistor and to the first output of the microammeter, which is a detector, and two transistors form an amplifier, while the first terminal of the third resistor is connected to the collectors of the transistors, and the other terminal is connected to the first terminal of the potentiometer, the potentiometer is connected by the second terminal to the fourth resistor, and the middle terminal with the second terminal of the microammeter, while the fourth resistor is connected by the second terminal to the second terminal of the second resistor and to the negative pole of the power supply, which is installed with the possibility of grounding, while the positive pole of the power supply is connected with the first output of the third resistor and the collectors of two transistors (see Pat.RU at PM No. 115636, IPC АВВ 5/04, publ. 05/10/2012).

The disadvantage of this method is the need for a large amount of source data for a reliable assessment of the measurement results.

The closest in technical essence and the achieved positive result and taken by the authors for the prototype is a method for assessing calf growth energy, consisting in the study of physiological parameters associated with growth energy, while the measurement of bioelectric potential in biologically active centers No. 5 is used as a physiological indicator, 7, 11, 41, 44, calculate the average value and, with a value of more than 48 μA, ascertain the high growth energy of calves (see US Pat. RU for IZ No. 2251263, IPC A01K 67/02, publ. 10.05.200 5 g., Bulletin No. 13).

The disadvantages of this method is the complexity of its implementation, namely, what is required:

- the presence of special skills in determining biologically active centers located on the skin of an animal;

- great complexity due to fixation of the animal;

- the need to use highly qualified specialists, significant funds for its implementation on sheep.

Disclosure of invention

The objective of the invention is to develop a method for predicting the individual growth rate of young sheep, with reduced labor costs, increased efficiency and accuracy in determining the intensity and nature of the growth of sheep, saving feed resources in accordance with the biological characteristics of a particular animal, which makes it possible to solve the technical problem of increasing efficiency and accuracy in determining the intensity and nature of the growth of sheep, saving feed resources in accordance Wii with the biological characteristics of a particular animal,

The technical result that can be obtained using the present invention is to reduce labor costs, increase efficiency and accuracy in determining the intensity and nature of the growth of sheep, saving feed resources in accordance with the biological characteristics of a particular animal.

The technical result is achieved using a method for determining the individual growth rate of young sheep, consisting in the study of physiological parameters related to growth energy, while the measurement of bioelectric potential is used as a physiological indicator, while the value of bioelectric potential is measured on any part of the sheep’s body using one electrode and with a value of bioelectric potential from 2.5 to 10 mV, they indicate intensive growth, and slow growth - from 20 to 6 0 mV, while the value from 10 to 20 mV corresponds to the transition period from intensive to slow or from slow to intense.

Thus, the technical result is achieved by the method of quickly determining individual growth and its characteristics (rhythm) in sex and age groups of animals, including the registration of individual bioelectropotential (BEP) of an individual using an upgraded device for determining the state of a living organism (see Pat. RU at PM No. 115636 " A device for measuring the electromagnetic radiation of an organism of farm animals ”Chavrenko VI, Zarytovsky AI, etc.), which allows to evaluate the general condition of the animal, its mass, the presence or absence of diseases, the effectiveness of the treatment, regardless of the amount of waste (excrement) accumulated inside the body and affecting its mass.

The selection of animals not only by sex and age groups, but also by the state of the individual organism, its BEP, allows you to selectively compose feeding diets, introduce the necessary biologically active substances in order to obtain their desired productive qualities.

The essence of the proposed method for predicting the growth rate of young sheep consists in the study of physiological indicators related to growth energy, while the physiological indicator is the measurement data of the bioelectric potential, which is measured in any part of the body using one electrode, and intensive growth corresponds to 2.5 to 15 mV, slow growth - from 20 to 60 mV, and a value of 15 to 20 mV corresponds to a transition period from intensive to slow or from slow to intensive, after which they constitute selective feed rations, both for the group and for each animal in the case of breeding.

Brief Description of the Drawings

In FIG. Figure 1 gives a method for predicting the individual growth rate of young sheep, the dependence of the dynamics of live weight gain on bioelectrical indicators of the mouse (male 1).

In FIG. 2 - the same, the dependence of the dynamics of growth in live weight of the mouse (male 2).

In FIG. 3 - the same, the dependence of the dynamics of live weight gain on bioelectrical indicators of the mouse (female 1).

In FIG. 4 - the same, the dependence of the dynamics of growth in live weight of the mouse (female 2).

In FIG. 5 - the same, the dependence of the dynamics of growth in live weight of the mouse (female 3).

In FIG. 6 - the same, the dependence of the dynamics of increase in live weight from bioelectrical indicators of the rat (male 1).

In FIG. 7 - the same, the dependence of the dynamics of increase in live weight from bioelectrical indicators of the rat (male 2).

In FIG. 8 - the same, the dependence of the dynamics of growth in live weight from rat bioelectrical indicators (female 1).

In FIG. 9 - the same, the dependence of the dynamics of the increase in live weight from the bioelectrical indicators of the rat (female 2).

In FIG. 10 - the same, the dependence of the dynamics of increase in live weight from bioelectrical indicators of the rat (female 3).

In FIG. 11 - the same, the dependence of the dynamics of gain in live weight from the bioelectrical indicators of the rabbit (male 1).

In FIG. 12 - the same, the dependence of the dynamics of increase in live weight from the bioelectrical indicators of the rabbit (male 2).

In FIG. 13 - the same, the dependence of the dynamics of the increase in live weight from the bioelectrical indicators of the rabbit (female 1).

In FIG. 14 - the same, the dependence of the dynamics of increase in live weight from the bioelectrical indicators of the rabbit (female 2).

In FIG. 15 - the same, the dependence of the dynamics of increase in live weight from bioelectrical indicators of a rabbit (female 3).

In FIG. 16 - the same, the dependence of the individual bioelectropotential on the value of the daily increase in live weight of the animal (bright 1).

In FIG. 17 - the same, the dependence of the individual bioelectropotential on the value of the daily increase in live weight of the animal (bright 2).

In FIG. 18 - the same, the dependence of the individual bioelectropotential on the value of the daily increase in live weight of the animal (bright 3).

In FIG. 19 - the same, the dependence of the individual bioelectropotential on the value of the daily increase in live weight of the animal (Valuh 1).

In FIG. 20 - the same, the dependence of the individual bioelectropotential on the value of the daily increase in live weight of the animal (wall 2).

In FIG. 21 - the same, the dependence of the individual bioelectropotential on the value of the daily increase in live weight of the animal (valukh 3).

In FIG. 22 - the same, the distribution of the bioelectropotential depending on the growth rate of live weight.

The implementation of the invention

Examples of specific performance of the method for predicting the growth rate of young sheep

Example. Intraspecific age and sex groups are formed in two groups: bright 1, bright 2 and bright 3, valuha 1, valuha 2 and valuha 3. In an animal (sheep) bioelectropotential is determined using an upgraded simple polygraph device (see Pat. RU on PM No. 115636 “Device for measuring electromagnetic radiation of farm animals ”), measuring the bioelectropotential using a polygraph is to use a rectifier (9 V) from the household power supply (220 V) to power the device and use one electrode (sensor) located on at a fixed distance from the surface of the animal’s body through a dielectric. Thus, the bioelectric potential of the animal is recorded through the electric charge and electric capacity of a living organism, recorded in mA or mV and correlated with the physiological state of the animal, and preliminary studies were performed on laboratory animals (mice, rats, rabbits), and a male is taken to measure the bioelectric potential 1 and female 2, respectively, of a mouse, rat, and rabbit, and by studying the dynamics of growth in live weight and BEP values show their inverse relationship in the graphs (see Fig. 1-15). The number of days of increase in daily gain in live weight in mice with a decrease in BEP averaged 63.3%, in rats - 65.6%, and in rabbits - 73.0%. The average for laboratory animals was 67.3%.

To predict the individual growth rate of young sheep, take bright 1, bright 2 and bright 3, valu 1, val 2 and val 3, while studies on young sheep show that an increase in the daily gain in live weight, regardless of the sex of the animal, entails a decrease in their value BEP (mV) (see Fig. 16-22).

The BEP is always positive. On the graph, its oscillations are above the zero mark, the abscissa axis (line). The rate of increase in live weight can have a positive and negative value, falling below zero. The calculation of the BEP indicators during the growth period of the lambs and their growth retardation, expressed as negative growth or equal to zero (growth stabilization), showed a significant difference.

The calculation of the BEP indicators during the growth period of the lambs and the growth retardation, expressed as negative growth or equal to zero (growth stabilization), is presented in the following examples:

Bright number 1. Intensive growth corresponds to an average BEP of 7.9 mV; growth retardation is observed at 20.33 mV; on days of unstable growth, the BEP was 14.6 mV (see Fig. 16).

Valukh No. 2. Intensive growth was with BEP - 9.75 mV, growth delay - 26.0 mV, and an unstable growth period - 16.9 mV (see Fig. 20).

Bright number 2. The intensive growth is 9.75 mV, the growth delay is 22.75 mV, and the unstable period is 10.87 mV (see Fig. 17).

Valukh number 1. Intensive growth - with BEP 8.5 mV, growth delay - 28.8 mV, unstable growth period - 19.5 mV (see Fig. 19).

Thus, an intensive increase in live weight in young sheep is observed when the BEP decreases below 10 mV, and a growth delay is accompanied by an increase in BEP above 20 mV. In transitional periods of growth intensity from maximum to minimum and vice versa, due to the growth rhythm (see Fedorov V.I., 1973, 272 s; Sipachev S.G., 1970, 352 s.), The BEP value is in the range of 10-20 mV (see Fig. 21).

From this it follows that it is possible to form groups of animals with the same BEP from the total number of young sheep, for each of which different veterinary measures should be applied (feeding regimes, stimulation, etc.) in order to maximize production and profitability of the sheep industry.

The number of days of mismatch in gain in live weight and an increase in BEP in lambs (%) (see table).

Similar data were obtained in laboratory animals.

This method of predicting the individual growth rate in young sheep makes it possible to apply selective feeding diets and conditions of detention depending on the magnitude of their bioelectric parameters.

The commercial livestock of young sheep when fattening them is divided into age and sex groups with the same individual BEP values, for which separate feeding diets are compiled in order to efficiently use feed resources and maximize productivity.

For breeding animals, an appropriate calculation of the diet for each individual is carried out.

The invention in comparison with the prototype and other known technical solutions has the following advantages:

- the efficiency of predicting individual growth of animals;

- saving feed resources in order to achieve maximum productivity;

- reduction of labor costs during breeding, breeding and other livestock breeding activities.

Claims (1)

A method for predicting the individual growth rate of young sheep, consisting in the study of physiological parameters associated with growth energy, while the measurement data of the bioelectric potential are used as a physiological indicator, characterized in that the value of the bioelectric potential is measured on any part of the sheep’s body using one electrode and with the value of the bioelectric potential is from 2.5 to 10 mV, intensive growth is noted, and slow growth is from 20 to 60 mV, while the value is from 10 to 2 0 mV corresponds to the transition period from intensive to slow or from slow to intense.

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