RU2806290C1 - Method for determining live weight of cattle - Google Patents

Abstract

FIELD: agriculture.

SUBSTANCE: method for determining the live weight of cattle includes measuring the exterior parameters, and additionally measuring the straight length of the hip region and the width of the buttocks at the ischial tuberosities, and based on the ratio of these values, the body index (BI) and the body mass index of the animal (BMI) are determined using the formula BI = √(Vbody/MG), (1) where BI is the body index, Vbody = 1/3 · SBL · (CD * CW + √(CD * CW * SLHA * DB) + SLHA * DB) , where SBL is the straight length of the body, CD is the depth of the chest, cm; CW is the chest width, cm; SLHA is the straight length of the hip area, cm; WB – width of the buttocks at the ischial tuberosities, cm; MG is the metacarpal girth, cm; BMI = BI / m, (2) where BMI is body mass index, m is live weight, kg, the value of body mass index (for heifers 0.341-0.347, bulls 0.282-0.289) is used as a coefficient for predicting the live weight of young animals.

EFFECT: invention allows the use of a non-contact method for determining live weight and body parameters of animals.

1 cl, 2 tbl

Description

The invention relates to agriculture, in particular to animal science, where live weight is determined to assess animal growth. The study of growth and development is necessary for a livestock specialist as knowledge of the basis on which biological characteristics and economic productivity develop, to assess the intensity of the formation of the organism in age dynamics, feeding control, to optimize veterinary treatment, and to determine the breeding value of the animal.

The animal body begins its existence from the moment of formation of the zygote and a complex path of growth and development of organs and tissues occurs, which leads to the formation of a certain constitutional type of an adult animal. In the individual development of animals (ontogenesis), two changes are distinguished:

- growth – quantitative increase in body weight, linear and volumetric dimensions;

-development (differentiation) – qualitative changes in the body associated with the formation of tissues and organs, the formation of their activity and changes in metabolism.

There is periodicity in growth and development, with periods of increased growth usually coinciding with periods of slow development and vice versa. The following patterns are characteristic of the ontogenesis of cattle:

- periodicity of growth and development;

- uneven growth and development at all ages;

-rhythm of growth and development.

To monitor the growth of animals, live weight is determined and measured on the first day after birth, and then at the following times: cattle and horses at 1 – 7, 9, 12, 18, 24 months; pigs at 1, 2, 4, 6, 9, 18, 24 months; sheep at 1, 4, 12, 24 months; Animals over two years old are weighed twice a year.

The traditional approach to determining live weight is based on the results of weighing the animal.

The disadvantages of the traditional method are:

- due to the unpredictability of the behavior and reaction of animals upon contact with an employee, the method is assessed as unsafe;

- weighing animals on scales causes a stress reaction;

- not all farms, and especially small farms, have special equipment;

There is a known method for determining the intrabreed body type of animals using the formula: ,

where IVVTT is an index of the severity of the intrabreed body type.

The essence of the method is that to assess the growth and development of an animal, its oblique length of the body, chest girth, height at the withers and rump are measured, the live weight is recorded by weighing, and by a certain ratio of these values and comparing them with standard parameters, the intra-breed exterior is judged. constitutional body type of animals [1].

The closest in technical essence is [2]:

- Trukhanovsky's method. The live weight of adult cattle is determined by measuring the straight length of the body and the girth of the chest behind the shoulder blades. For this, the formula proposed by Trukhanovsky is used:

where M is the live weight of the animal, kg

A – chest circumference behind the shoulder blades, cm;

B – straight length of the body, determined by the distance from the highest point of the withers along the line of the back to the root of the tail, cm;

K – correction factor (2 for dairy cattle and 2.5 for dairy and meat breeds);

- the Kluwer-Strauch method, which consists in the fact that based on the results of measuring the girth of the chest behind the shoulder blades and the oblique length of the body, the live weight of the animal is calculated using a special table;

- Frowein's method. The live weight of young cattle is determined by measuring the girth of the chest behind the shoulder blades and the oblique length of the body, and the live weight of the animal is determined using a special table.

The disadvantage of these methods is:

- a limited number of animal body measurements are taken into account, and they do not fully characterize the exterior-constitutional indicators, therefore, data on the complex body type and individual biological characteristics of animals are not sufficiently complete;

- when determining live weight based on body measurements, an adjustment is made for condition: for animals of above-average fatness, the estimated weight is increased by 5-10%, for animals below average fatness, the estimated weight is reduced by 5-10%. This indicates a high error in determining the live weight of the animal.

The purpose of the present invention is to use a non-contact method for determining live weight and body parameters of animals. Based on the measurements taken and using the author’s formula, a complex exterior index (trunk index, IT) and a coefficient for predicting live weight based on body parameters (body mass index BMI) were determined.

The essence of the invention lies in the fact that in farm conditions, when keeping animals in stalls, exterior parameters were determined by measuring measurements and, using a certain ratio of these values, new proprietary formulas were used for the first time to calculate the complex body index and live weight prediction coefficient.

, (1)

where IT is the torso index,

, SDT – straight body length, GG – chest depth, cm; SH – chest width, cm; DTOB – straight length of the hip area, cm; ШЗ – width of the buttocks at the ischial tuberosities, cm; OP – metacarpal girth, cm

, (2)

where BMI is body mass index,

m – live weight, kg.

This method was carried out as follows. Initially, at agricultural enterprises of the Udmurt Republic, 253 heads of young animals (aged 18 months) of different origin were assessed by exterior: 128 bulls raised for meat and 125 heifers raised for herd replacement. All animals were divided into three groups depending on their origin: group 1 - bulls and heifers of the black and white breed; Group 2 – bulls and heifers of the Aberdeen Angus breed; Group 3 – crossbred bulls and heifers of the first generation, obtained by crossing black-and-white cows with Aberdeen-Angus stud bulls. Quantitative parameters of the following measurements were determined: straight length of the body, chest depth, chest width, width of the buttocks at the ischial tuberosities, straight length of the hip area, metacarpal girth. These parameters most accurately characterize the dimensions (frame) of the animal, and their totality represents a three-dimensional figure - a truncated pyramid. Thus, the complex body index is a dimensionless value showing the relationship between the average linear size of the animal’s overall size and the girth of the metacarpus. The metacarpal girth measurement is included in the formula to take into account the development of the skeletal system.

Exterior parameters were determined by the method of processing images obtained using a depth sensor – Structure Sensor 3D. The depth sensor is a camera that attaches to a tablet device and allows you to capture a three-dimensional image of objects. The sensor software allows you to obtain information about the distance between objects, the distance from the camera to the object, and determine any linear size of the object itself in real time. The main significant advantage of using a depth sensor is the ability to determine the size of an object without stressing animals. From the resulting animal model, all studied exterior parameters were determined.

Productivity, conformation and live weight are interconnected and reflect the metabolism characteristic of each individual. The study of conformation is based on three basic principles:

- the direction of the animal’s productivity and its level are reflected in the body features;

- external body shapes are correlated with each other and with the development of the animal’s internal organs;

- exterior features are determined by the breed characteristics of the animal.

The characteristics of the studies of the analyzed groups of young animals according to exterior indicators are given in Table 1.

Our assessment of the exterior parameters of bulls and heifers showed that the animals have a strong and deep body, good body height development parameters, and correctly positioned front and rear limbs. The development of exterior characteristics of the young animals of the analyzed groups has a fairly even character. The variability of the studied traits varied from 2.9% to 17.4%. The variability of the selection and genetic parameters of the physique and growth rate of young animals of the black-and-white breed was in the range of 2.9-8.7%, for the purebred Aberdeen-Angus breed 2.1-11.5%, and for crossbred young animals, respectively, 5.3-17 ,4%. In terms of body traits, both bulls and heifers have relatively low variability. The least variable characteristics are animal height (2.9-8.7%) and straight length of the hip region (3.4-9.5%). The maximum variability was observed in average daily gain (5.9-17.4%), live weight (5.7-16.9%) and pastern girth (8.2-13.2%).

A comparative analysis of the exterior-constitutional characteristics of animals of different breeds showed that the body type of the analyzed livestock corresponds to the genetically determined direction of productivity and the animals have distinctive characteristics. Heifers and bulls of the black-and-white breed have a more elongated physique. At the same time, their superiority over their peers of the Aberdeen Angus breed in straight body length was revealed by 4.2% and 2.7% (P <0.05), while being slightly inferior in height at the withers by 1.1% and 1.9 %. Young animals of the Aberdeen Angus breed as beef cattle have a more voluminous body, a well-built body type with a well-developed thoracic region and the rear third of the body. Heifers and bulls of group 2 are superior to their peers of group 1 in chest width by 6.7% and 8.3% (P <0.05), chest depth by 8.9% (P <0.05) and 11.4% (P <0.01), buttock width at the ischial tuberosities 33.2% and 36.6% (P <0.001). Meat breed animals are characterized by stronger development of the skeletal system. Pastern girth in young Aberdeen Angus breeds was higher by 10.6% and 12.8% (P < 0.05). Crossbred animals (group 3) occupy an intermediate position mainly in all analyzed exterior parameters.

Individual measurements, considered in isolation from each other, do not characterize the exterior of the animal as a whole and do not give a complete picture of the body type and development of the organism as a whole. Therefore, in practice, they are most often expressed in relation to each other or as a percentage of some basic measurement, that is, physique indices are calculated. The formula we developed for determining the body index allowed us to conduct a comprehensive assessment of the exterior in numerical terms (Table 1). The results obtained show that the average body conformation index in the studied sample of animals is a relatively constant value and varies between groups: for heifers in the range of 6.3-7.8%; in bulls 7.2-7.8%. The analyzed complex exterior index (trunk index) indicates the genetic conditioning of the formation of body type in cattle of different directions of productivity.

Table 1. Selection and genetic indicators of the exterior and live weight of heifers and bulls (age 18 months). (a) Group 1 (black and white breed)

Index Chicks Gobies ±Δx Cv,% lim ±Δx Cv,% lim Live weight, kg 371.8±4.7 8.1 361-420 478.0±4.4 5.7 457-502 Average daily increase, g 657.5±18.9 5.9 596.5-765.3 782.9±18.2 6.1 697-853 Height at withers, cm 126.9±0.5 2.9 121.2-132.7 129.9±0.8 3.5 123.4-132.7 Straight body length, cm 128.7±1.4 3.7 125.2-134.8 138.9±0.9 2.4 134.8-145.1 Chest width, cm 37.3±0.4 7.2 34.3-42.30 40.2±0.9 3.7 37.2-45.6 Chest depth, cm 67.6±0.4 3.3 62.4-69.6 71.2±0.6 5.1 63.7-75.8 Width in macrolocks, cm 45.6±0.9 3.5 40.3-51.0 47.2±0.6 7.5 39.9-53.1 Straight length of the hip area, cm 79.1±0.4 3.4 73.5-84.0 78.1±0.5 3.4 73.5-85.4 Metacarpal girth, cm 19.4±0.6 8.7 16.0-21.0 20.2±0.5 8.2 18.3-22.7 Width of the buttocks at the ischial tuberosities, cm 29.3±0.6 4.5 24.5-33.7 31.7±0.9 5.7 26.4-34.3 Trunk index 126.8±2.9 9.1 122.7-131.2 135.3±1.5 5.3 131.5-140.6 Body mass index 0.341±0.011 11.4 0.331-0.342 0.283±0.002 8.8 0.267-0.291

(b) Group 2 (Aberdeen Angus breed) Index Chicks Gobies ±Δx Cv,% lim ±Δx Cv,% lim Live weight, kg 388.9±8.9 9.5 362-405 515.2±2.50 6.9 459-535 Average daily increase, g 659.7±19.3 9.9 598.2-689.4 844.7±17.6 7.1 791.3-1032.5 Height at withers, cm 128.2±2.7 8.7 125.4-137.5 132.5±1.5 3.1 127.7-141.5 Straight body length, cm 125.6±2.1 10.8 121.1-132.8 135.3±1.5 6.9 131.3-142.9 Chest width, cm 39.8±0.6 9.5 35.6-43.4 43.5±0.5 2.9 37.4-47.1 Chest depth, cm 73.7±1.6 9.2 67.9-80.5 79.3±1.2 2.1 71.5-87.1 Width in macrolocks, cm 42.2±1.8 7.4 38.1-46.4 46.7±2.2 10.4 41.0-52.8 Straight length of the hip area, cm 84.3±1.9 7.9 78.2-90.6 85.0±5.5 8.6 81.4-92.1 Pastern girth, cm 21.5±0.5 8.3 19.3-23.1 22.8±0.7 9.5 18.3-24.8 Width of the buttocks at the ischial tuberosities, cm 39.1±0.8 9.0 34.5-43.7 43.4±1.5 6.7 37.2-46.7 Trunk index 134.9±3.6 11.2 134.1-146.81 145.4±3.1 3.6 138.4-152.7 Body mass index 0.347±0.004 4.7 0.345-0.351 0.282±0.001 7.7 0.279-0.289 (c) Group 3 (1st generation crossbreeds - Black and White and Aberdeen Angus breeds) Index Chicks Gobies ±Δx Cv,% lim ±Δx Cv,% lim Live weight, kg 394.3±4.5 16.9 357-442 502.7±6.7 12.3 475-529 Average daily increase, g 624.5±28.6 17.4 578.2-704.5 884.6±20.2 13.6 830.5-1045.7 Height at withers, cm 130.4±8.9 6.5 124.9-135.3 132.3±2.6 6.3 125.9-141.3 Straight body length, cm 125.1±7.1 15.3 117.1-133.7 132.5±2.8 8.2 124.7-137.0 Chest width, cm 38.2±0.6 7.5 35.5-41.4 41.9±1.9 11.6 36.9-44.8 Chest depth, cm 71.8±3.6 13.4 67.6-75.2 78.6±2.5 5.3 74.7-85.1 Width in macrolocks, cm 43.4±1.5 8.3 39.0-46.9 47.2±1.7 6.3 43.8-51.0 Straight length of the hip area, cm 99.8±3.8 9.5 94.1-106.5 105.1±2.7 6.2 101.3-110.7 Pastern girth, cm 21.6±1.3 13.2 18.2-23.4 23.8±0.6 9.6 21.7-24.9 Width of the buttocks at the ischial tuberosities, cm 37.5±1.0 6.4 34.9-41.5 41.1±0.9 3.9 37.2-43.9 Trunk index 136.7±6.9 14.2 132.8-146.9 145.1±3.0 3.9 139.6-154.7 Body mass index 0.347±0.009 11.4 0.341-0.353 0.289±0.009 5.7 0.281-0.292

Exterior traits, live weight and growth rate of livestock are characterized by a certain relationship with each other. Many traits are positively or negatively related to each other. In this case, the relationship between the characteristics can be strong or weak (Table 2).

A certain relationship was revealed between exterior, live weight and average daily gains, and varied from minus 0.09 to +0.76. A high positive correlation was found in the indicators “straight body length – live weight” (0.65-0.76), “straight body length – average daily gain” (0.47-0.51), “chest depth – live weight” (0.62-0.68), “rear width at the ischial tuberosities – live weight” (0.61-0.73) “rear width at the ischial tuberosities – average daily gain” (0.55-0.64).

Table 2. Relationship between exterior parameters, live weight and average daily gains.

Gobies Chicks Live weight Average daily growth Live weight Average daily growth Height at withers, cm 0.54 0.34 0.32 0.43 Straight body length, cm 0.65 0.47 0.76 0.51 Chest width, cm 0.32 0.25 0.47 0.25 Chest depth, cm 0.68 0.38 0.62 0.43 Width in macrolocks, cm 0.68 0.54 0.66 0.33 Straight length of the hip area, cm 0.33 0.31 0.24 0.39 Width of the buttocks at the ischial tuberosities 0.73 0.64 0.61 0.55 Metacarpal girth, cm -0.13 -0.09 -0.11 -0.14 Trunk index 0.77 0.59 0.65 0.68

A weak (close to zero) negative correlation was noted between pastern girth with live weight (0.11-0.13) and average daily gains (0.09-0.14). A high positive relationship was revealed between “complex body index - live weight” (0.61-0.73) and “complex body index - average daily gain” (0.55-0.64). Based on the identified biological patterns of the relationship between the physique of animals and their live weight, a live weight prediction coefficient (body mass index) was established, which was 0.341-0.347 for heifers, and 0.282-0.289 for bulls.

Thus, the identified biological pattern of formation of the exterior-constitutional characteristics of cattle in age dynamics and the established close relationship between body parameters and growth rate give reason to believe that the calculated body mass index value (in heifers 0.341-0.347, bulls 0.282-0.289 ) can be used as a coefficient for predicting the live weight of young animals without using a labor-intensive weighing process.

List of used literature:

1. Patent No. 2285398 C2 Russian Federation, IPC A01K 67/02. Method for determining the intrabreed body type of animals: No. 2003129962/13: application. 10/08/2003: publ. 10.20.2006 / B. O. Inerbaev, N. V. Borisov, E. A. Yurchenko; applicant State scientific institution Siberian Research and Design and Technological Institute of Animal Husbandry (GNU SibNIPTIZH).

2. Izilov, Yu. S. Workshop on cattle breeding / Yu.S. Izilov. - M.: KolosS, 2013. - 183 p.

Claims (9)

A method for determining the live weight of cattle, including measuring exterior parameters, characterized in that the straight length of the hip region and the width of the rear at the ischial tuberosities are additionally measured, and based on the ratio of these values, the body index (TI) and the body mass index of the animal (BMI) are determined using the formula ) , (1) where IT is the torso index, , where SDT is the straight length of the body, GG is the depth of the chest, cm; SH – chest width, cm; DTOB – straight length of the hip area, cm; ШЗ – width of the buttocks at the ischial tuberosities, cm; OP – metacarpal girth, cm , (2) where BMI is body mass index, m – live weight, kg., the value of body mass index (for heifers 0.341-0.347, bulls 0.282-0.289) is used as a coefficient for predicting the live weight of young animals.