RU156767U1 - INSTALLATION FOR NON-SURGICAL EXTRACTION OF EMBRYOS IN ANIMALS - Google Patents

Abstract

Installation for non-surgical extraction of embryos in animals, including a container designed to accommodate flushing fluid with a base mounted on the container, in which a return, pneumatic and intake opening are made, and the container is connected to the embryo collector through the return opening using the nozzle provided with the embryo collector , the pneumatic adjustment hole is made open with the possibility of regulating the internal air pressure in the tank, characterized in that the base on its outer side, along its entire perimeter, has a side wall forming a chamber together with the base, on the outer side of which, in addition, partitions are installed that divide this chamber into filter, intake-discharge and battery blocks, while the return and pneumatic adjustment openings are made at the base at the location of the filter unit, the intake hole is made at the base at the location of the intake-pumping unit, in addition, at the intake hole of the intake-pumping unit a suction and discharge element is installed on the unit in the form of a pump with an intake and discharge nozzles, configured to create an adjustable pressure gradient when the washing fluid moves, while the intake and discharge element is attached to the base due to the intake nozzle installed in the intake opening so that the lower open end of the intake pipe is located under the base inside the tank, in addition, the intake-discharge and battery units are closed by a lid with a hole in it

Description

The utility model relates to the field of reproductive biotechnologies in animal husbandry, in particular, to devices for non-surgical extraction of embryos from the horns of the uterus of animals in the technology of multiple ovulation and embryo transplantation.

For non-surgical extraction of embryos in animals, systems are used that, as a rule, contain devices: a catheter designed to be inserted into the uterine cavity of the animal, to which, in a certain sequence, pipelines are connected to a device for collecting and localizing embryos (embryo collector), capacity with flushing fluid, a syringe designed to be sucked through the piping of flushing fluid from the reservoir and for supplying this fluid through pipelines to the uterine cavity, a syringe for feeding air into the catheter. Due to these devices, a closed loop is created for circulating the flushing fluid through the uterine horn cavity and through the system. The procedure for washing embryos in one animal consists of repeatedly repeated cycles of washing fluid circulation along the created closed loop, the use of which reduces the likelihood of contamination of the washing fluid and reduces its use. Each of the cycles includes successive steps: taking the required volume of flushing fluid from the reservoir, feeding this flushing fluid through the pipelines and catheter into the uterine horn cavity, outflow of flushing fluid along with embryos from the uterine horn through the catheter and pipelines into the embryo collector in which localization and collection of the recovered embryos by filtering the washing liquid containing washed embryos, returning the embryo-free washing liquid from the embryos collection, through es conduits back into the container. To obtain the maximum number of embryos, the procedure for their extraction is carried out with repeatedly repeated cycles.

A set of equipment for non-surgical embryo extraction is known (hereinafter, the system for non-surgical embryo extraction), which provides for closed circulation of flushing fluid during the procedure for flushing embryos from the uterus of the animal, including a three-channel catheter for removing embryos, a bottle for flushing fluid (supply container), a bottle for collecting embryos (receptacle) or retaining filter embryos in a small amount of liquid syringe 50-100 cm ³ for supplying flushing liquid from feeding capacity through hoses into the uterine cavity of the animal, a syringe for supplying air to an inflatable balloon of a three-channel catheter, a system of hoses with clamps that ensure connection between each other in a certain sequence of these devices for the purpose of closed circulation of flushing fluid, a thermostat (electric heating cabinet) to accommodate the supply and reception containers (VV Madison, VL Madison. Transplantation of embryos in the practice of breeding dairy cattle. - M: VO Agropromizdat, 1988, pp. 67-71). A three-channel catheter is a tube with channels made inside it, one of which is an air channel with an inflatable balloon at the end near the distal end of the catheter, the second channel is designed for introducing the flushing fluid into the uterine horn cavity, and the third channel for flushing the flushing fluid containing the washed out embryos from the uterine horn cavity. A plastic cannula with 2 lateral openings is attached to the distal end of the catheter, and the proximal end is made into in the form of connectors dividing three channels between each other for separate access to each of the 3 channels in order to connect the corresponding hoses to them.The procedure for embryo extraction is that the operator inserts a three-channel catheter into one of the uterine horns, performs a rectogenital examination of the catheter fixation site in the uterus and using a syringe to supply air through the air channel, fills an inflatable balloon with air, which, in a straightened form, covers the cavity of the uterine horn, reliably fixing the catheter. The assistant operator connects the hoses to the connectors of the three-channel catheter, to which all other equipment of the system for non-surgical embryo extraction is connected. An embryo leaching process is carried out, consisting of repeatedly repeated cycles of washing fluid circulation through the system and through the internal cavity of the uterine horn, to obtain the maximum number of embryos. In practice, 10-15 cycles are carried out, while for a single cycle, the flow rate of flushing fluid is on average 30-50 ml, and for the complete procedure for washing one horn of the uterus, on average 300-500 ml. The duration of washing in one animal is 20-30 minutes.

The disadvantage of using such a system is that several specialists with professional skills should be involved in the procedure for washing the embryos. In addition, for such specialists, a prerequisite for the efficient extraction of embryos is the strict observance of synchronism and sequence of actions during all the steps, not only in one cycle of washing liquid circulation, but also in each of the repeated cycles, since the washing liquid circulation is adjusted manually manipulations with clamps on hoses, with a syringe for supplying air to an inflatable balloon of a three-channel catheter, with a syringe for supplying flushing liquid STI At the same time, due to the human factor, the risk of disruption of the sequence of manipulations can increase, leading to a loss in the efficiency of extraction and collection of embryos.

The prototype of the claimed utility model is the design of a system for non-surgical extraction of closed-loop embryos, described in US Pat. No. 5,042,979 (hereinafter referred to as the system), in the part represented by a container intended to contain washing liquid and connected to a syringe for suction and supply of washing liquid. The upper part of the tank is made in the form of a base (or cover), through the structural elements of which are supplied to the system and return from the washing fluid system due to the fact that the base, through the pipelines built into it, connects the tank with an extensive network of pipelines, which in turn connect the tank with a syringe for suction and delivery of flushing fluid (hereinafter - the syringe), as well as with other devices that the system is equipped with: with a catheter for insertion into the uterine cavity and with an embryo filter (device embryo collection facility, embryo collection). The container, according to the patent US 5042979, can be made of glass or plastic in various ways, including in the form of a container with a lid or a closed container with a base in the upper part, as well as in the form of an elastic bag with a upper base. For all types of containers in the base (or in the lid) there are intake, return, pneumatic adjustment holes and a hole with a stopper. A pipeline is drawn through the intake opening, the upper open end of which is located above the base, and its lower open end is located under the base near the bottom of the tank. The upper open end of this pipeline, according to the original description and drawing of the prototype in figure 1, is intended for connection with a pipeline connecting a container with a syringe for suction and supply of flushing fluid (hereinafter - the syringe), as well as with other pipelines and devices in the system. Thus, the intake hole is configured to collect flushing fluid from the reservoir for supplying this fluid to the uterus of the animal through the pipelines of the system for non-surgical extraction of embryos with a closed loop. At the same time, the syringe connected to the container via pipelines is located at a considerable spatial distance from the container, which is due to the fact that the syringe is also connected through many pipelines to other devices in the system: with a catheter and embryo collector, which are also located at a considerable spatial distance from the tank. A return hole is made in the base with the possibility of returning the washing fluid to the tank from the uterus of the animal through the pipelines of the system, since a fitting is installed in the return hole for connecting to pipelines connected to the embryo filter. The air control hole in the base is open with the possibility of regulating the internal air pressure in a container containing washing medium, during the implementation of the entire process of washing out the embryos. The hole in the base, closed by a stopper, is made for the case of using a closed container, and serves as an opening for pouring washing liquid into the container. To create a circulation of flushing fluid in a closed circuit, it is sucked from the tank through the corresponding pipelines by means of a syringe and stage-by-stage movement of flushing fluid in the closed circuit of the system is carried out using the same syringe, as well as by closing or opening many pipelines with clamps and valves at all stages of the intake fluid from the reservoir, by feeding it into the uterine cavity and outflow from the uterus, as well as by redirecting it to the embryo collection chamber and returning it to the reservoir.

The cycle of circulation of flushing fluid in this system and in the internal cavity of the uterus of an animal consists of several stages, which are carried out through numerous manipulations with clamps and valves in the pipelines, as well as with a syringe for suction and supply of flushing fluid. In order to collect flushing fluid from a container into a given syringe, the operator and assistant must use all clamps or valves to shut off all pipelines that connect the syringe and embryo-catheter to the catheter and ensure the outflow of flushing fluid from the internal uterine cavity, and, accordingly, it is necessary to open all clamps and valves on pipelines connecting the syringe to the container. After that, washing liquid is also manually taken from the tank through the pipelines using a syringe. Then, in order to feed the flushing fluid collected from the container into the syringe into the uterine cavity, it is necessary to close the clamp or valve on the pipeline connecting the syringe to the container and open the clamp or valve connecting the syringe to the catheter through which flushing fluid is supplied into the cavity of the uterus, and at the same time, it is necessary to ensure that the clamp located on the pipeline connecting the catheter to the embryo catcher is in the closed position. After that, it is necessary to quickly close the clamp located on the pipeline connecting the syringe to the catheter, and also to open the clamp on the pipeline connecting the catheter to the embryo collection and the valve on the pipeline connecting the embryo to the container as quickly as possible. The complex of the above manipulations is the implementation of only one cycle of washing fluid circulation through the system and through the uterine cavity. Each cycle must be started from the starting position and must be repeated many times in order to extract and collect the maximum number of embryos.

The disadvantages of the prototype are the increased loss of recoverable embryos due to the following reasons. Due to the fact that one cycle is not enough to completely wash out the embryos, and the cycles must be repeated repeatedly, interruptions are necessary between cycles due to the design of the system, in which the container at a spatial distance from it is connected by pipelines containing clamps, valves, and tees , with a syringe for suction and supply of flushing fluid, as well as with all other structural elements of the system. A break between cycles is carried out so that the residual flushing fluid located in the pipeline connected to the embryo collector, in the embryo-collector, as well as in the pipeline connecting the embryo-collector to the tank, completely empty these structural elements of the system to avoid re-suction at the beginning of the next cycle of unfiltered washing fluid containing embryos back into the syringe, or to avoid re-injection of this washing fluid with embryos back into the uterine cavity. Failure to observe the break between cycles leads to the loss of a significant number of embryos. However, even during these breaks between cycles, there is a high risk of loss of recoverable embryos due to an increase in the number of manipulations with the structural elements of the system during subsequent repeated cycles, since the procedure for extracting embryos using this system involves numerous manual manipulations with the syringe plunger, as well as clamps and valves on pipelines, which must be carried out in a strictly defined sequence. The design of the system does not allow the syringe body to be fixed to anything, which is located at a considerable spatial distance from the container, and as a result, it can be fixed only by the operator’s hand during the entire embryo washout procedure, while this operator synchronously holds with the other hand rectal monitoring of the location of the air balloon inside the uterine horn and the degree of filling of the uterine horn with flushing fluid, which makes it impossible for the operator in the absence of an assistant assistant conducting manipulations with the pipelines according to the position of the clamps “open-closed”, as well as carrying out actions with the syringe plunger associated with the injection of a certain volume of flushing fluid into the syringe, forcing this collected fluid into the pipelines for the purpose of its delivery to the uterine cavity, as well as with redirection into the embryo collector of washing liquid, into which embryos are separated from the uterus, and returning from the embryo collector back to the container of the washing liquid filtered from the embryos. Even if there are several operators, there is a high probability of errors in implementing the provisions of the clamps and valves “closed-open”, as a result of which there is an increased risk of violation of the stages in the intake, in the supply and outflow of flushing fluid. In this case, washed embryos may be lost, since they, together with the outflow of washing liquid, may not enter the embryo filter (device for collecting embryos), but into the syringe or container. In addition, when manually applying pressure to the syringe plunger at the stages of flushing fluid supply in different cycles through the system into the uterine horn cavity, the pressure gradient when the flushing fluid moves from the reservoir to the animal’s uterus through the pipelines can be changeable: either insufficient for efficient extraction of embryos, or excessively strong . With an insufficient pressure gradient, a weak filling of the uterine horn with the washing liquid occurs, and, as a result, the embryos are displaced to the top of the uterine horn, in which they settle. Such embryos become less accessible for extraction during washing. An excessive pressure gradient can lead to a violation of the integrity of the system, especially at the junctions of its structural elements, and to the loss of the supplied flushing fluid. As a result, the embryo extraction procedure may be interrupted. In addition, an increased pressure gradient can lead to an excess volume of flushing fluid entering the uterine horn and expanding the size of the uterine horn, whereby flushing fluid with recoverable embryos spills beyond the borders of the inflatable balloon into the body and cervix, and the embryos become inaccessible for extraction. The long duration of the process of washing the embryos, ranging from 20 to 30 minutes of time per animal, leads to a decrease in the effect of anesthesia in the animal, while increasing its sensitivity to rectal manipulations of the operator and to the presence of a catheter in the uterus, which helps to reduce the uterus of the animal, and, as consequence, to irritation of its mucous membrane, to bleeding in the uterus and rectum of the animal, and to the forced termination of the process of washing out the embryos. Due to the long network of pipelines, when the fluid passes from the reservoir to the uterine horn, the flushing fluid loses the necessary temperature and leads to thermal shock of the embryos, which reduces their viability during further manipulations with the embryos.

The technical task of the utility model is to create a device that increases the collection of embryos.

The technical result of the utility model is to increase the collection of embryos by ensuring the continuity of the circulation cycles of the washing fluid during the procedure of washing the embryos from the uterus of the animal using the system for non-surgical extraction of closed-loop embryos.

The technical result is achieved by the fact that the installation for non-surgical extraction of embryos in animals includes a container 1 intended for placement of washing liquid in it, with a base 2 installed on the container 1, in which a return 3, pneumatic 4 and intake 5 openings are made, while the container 1 connected to the embryo collector 6 through the return opening 3 by means of the pipe, which is equipped with the embryo collector 6, the pneumatic adjustment hole 4 is made open with the possibility of regulation internally air pressure in the tank 1. On the base 2, on its outer side, along its entire perimeter, a side wall 7 is formed, forming a chamber together with a base 2, on the outer side of which, in addition, partitions 8 and 9 are installed, separating this chamber into a filter 10 , intake-pumping 11 and accumulator 12 blocks, while return 3 and pneumatic 4 holes are made in the base 2 at the location of the filter unit 10, the intake hole 5 is made in the base 2 at the location of the intake-pumping block 11, cr Moreover, in the intake hole 5 of the intake-pumping unit 11, an intake-pumping element 13 is installed in the form of a pump with an intake 14 and discharge 15 nozzles, configured to create an adjustable pressure gradient when the washing fluid moves, while the intake-pumping element 13 is attached to the base 2 due to the intake pipe 14 installed in the intake hole 5 so that the lower open end of the intake pipe 14 is located under the base 2 inside the tank 1, in addition, the intake-blower The 11th and accumulator 12 blocks are closed by a cover 16 with an opening 17 made therein, installed at the location of the intake-pumping unit 11, while in this hole 17 a fitting 18 is installed for connecting to the discharge pipe 15, in addition, in the battery block 12, a power supply unit 19 is connected to the intake-discharge element 13.

The figure shows a General view of the installation for non-surgical extraction of embryos in animals (vertical section).

Installation for non-surgical extraction of embryos in animals works as follows. It can be used during the procedure of washing embryos from the uterus of animals, in particular in cattle, horses and other large animals.

The installation is designed to connect via pipelines to a three-channel catheter for the extraction of embryos, which is a tool for introducing into the uterine cavity of the animal, through the channels of which the washing liquid is introduced into the uterine cavity and the outflow of washing liquid along with the embryos. At the same time, inside the three-channel catheter 20 there is an air channel 23 with an inflatable balloon 28 at the end, a channel 21 for introducing the flushing fluid into the uterine horn cavity, and a channel 22 for flushing fluid containing flushed embryos from the uterine horn. Pipelines and boat should be made of polymers with flexibility, elasticity and translucency.

Installation for non-surgical extraction of embryos in animals can be manufactured industrially from biologically safe polymers. During its manufacture, an embryo collector 6 is built into the return opening 3 of the filter unit 10 due to its nozzle. A device for collecting animal embryos (patent of the Russian Federation for utility model No. 153867, application for a patent for utility model of the Russian Federation No. 2015116725) of the copyright holder of the Center for Experimental Embryology and Reproductive Biotechnology Federal State Budgetary Institution TsEERB ), tested in the extraction of embryos from donor cows in a number of Russian farms. This device facilitates the time-consuming process of collecting embryos and eliminates the loss of washed full embryos as much as possible.

Also, in the manufacture of a device for non-surgical extraction of embryos, an intake-pumping element 13 is built in its intake-pumping unit 11, which is made in the form of a pump with a sampling 14 and discharge 15 nozzles attached to it. In this case, the intake pipe 14 must be installed in the intake hole 5 of the base 2 so that the lower open end of the intake pipe 14 is located under the base 2 inside the tank 1, and the discharge pipe 15 is designed to be connected to the pipeline through which the discharge pipe 15 connected to the channel 21 of the three-channel catheter 20. The pump 13 must contain a mechanism that allows simultaneous intake of the washing fluid from the tank 1 and its injection with an adjustable gradient and I. The specified pump can be performed with a centrifugal principle of operation (rotary, etc.) with an electric or mechanical drive. In particular, a pump with an electric drive "Ekar" manufactured by LLC "ECAR-ENVO" (Voronezh.) Can be used. An electrically driven pump is provided with an electronic control unit 27 and an electrical power unit 19 installed in the battery unit 12 and connected to the intake-discharge element 13. The intake-discharge element 13 is configured to create an adjustable pressure gradient when the washing fluid moves due to the electronic control unit 27 , allowing you to set a constant pressure gradient throughout the procedure for washing the embryos. At the same time, the necessary pressure gradient is set at the discretion of the operator, depending on the width and length of the catheter used.

Before using the apparatus for non-surgical extraction of embryos from animals, a three-channel catheter 20 is prepared for operation with a preliminary check of the integrity of the inflatable balloon 28. To do this, connect a syringe 24 with 15-20 cm ^{3 of} air drawn into it and pressing the syringe 24 on the piston introduce air into the inflatable balloon 28. After making sure that there is no violation of the integrity of the inflatable balloon 28, the syringe 24 is disconnected and air is removed from this balloon due to the fact that the three-channel catheter 20 is to be introduced feeding into the uterine cavity of the animal when the inflatable balloon 28 is empty. Then the syringe 24 with the air drawn into it is reconnected to the air channel 23, and a stylet (mandrin), which is an auxiliary tool, is introduced into the channel 22 to stiffen the three-channel catheter 20 when it is inserted into uterine horn of an animal.

Then the donor animal is fixed in the machine and preparatory procedures are carried out: low sacral anesthesia by introducing a 2% solution of novocaine into the epidural space between the first and second caudal vertebrae, and sanitary-hygienic treatment of the external genital organs.

After fixation, a three-channel catheter 20 is introduced into the donor animal, in which its distal end is passed through the vagina and cervix of the animal, and the catheter 20 is inserted into one of the uterine horns 29. The catheter 20 is moved deep into the uterine horn and at the same time a stylet is removed by a third with the implementation of rectogenital determination of the fixation site of the catheter 20 in the uterus. When the distal end of the catheter 20 reaches the location in the internal cavity of the uterine horn, as a place for optimal extraction of embryos, air is injected into the inflatable balloon 28 through the air channel 23 using a syringe 24, which in its expanded form covers the uterine horn cavity, reliably fixing the three-channel catheter 20. After fixing the catheter 20 in the cavity of the uterine horn, the stylet is removed from the catheter 20.

A three-channel catheter 20 fixed in the internal cavity of the uterine horn is connected via pipelines to a device for non-surgical extraction of embryos in animals in the following order. Its channel 21, intended for introducing the washing fluid into the uterine horn cavity, is connected to the pipeline 25, as well as the channel 22, used to remove the washing liquid containing the washed out embryos from the uterine cavity, with the pipeline 26. Thus, the internal cavity of the uterine horn through the catheter 20 and the interconnected structural elements of the installation form a closed loop for the circulation of flushing fluid, through which embryos will be washed out of the uterus of the animal. In this form, the device is ready for use.

The implementation of continuous cycles of circulation of the washing fluid in a closed circuit is carried out by taking the washing fluid from the tank 1 using the intake and injection element 13. The washing of the washing fluid is started by turning on the electronic control unit 27, while the rectogenital control of filling the uterine cavity with washing fluid is simultaneously performed . From the moment the electronic control unit 27 is turned on, the pump 13 begins to withdraw the washing liquid from the tank 1 through the intake pipe 14 with the simultaneous injection of the washing liquid through the discharge pipe 15 into the pipe 25, through which the washing liquid is sent to the channel 21 of the three-channel catheter 20. After passing through the channel 21, flushing fluid from its distal end enters the cavity of the uterine horn, fills it and raises embryos from the endometrium. In this case, due to the operation of the pump 13, a predetermined constant pressure gradient is ensured during the movement of the washing liquid, which prevents embryos from settling and stimulates their exit together with the washing liquid into the channel 22 of the three-channel catheter 20. At the same time, the inflatable balloon 28, which in its expanded form covers the horn cavity 29 of the uterus, prevents the exit of fluid coming from the channel 21, in places in contact with the walls of the uterine horn. The flushing fluid, which continues to come from the channel 21, overflows the cavity of the top of the uterine horn and, with its excess, leaves the uterus together with the embryos through the channel 22 of the three-channel catheter 20 into the pipe 26 connected to the embryo collector 6. The flushing fluid with the embryos passing through the embryo collector 6 is filtered, and the embryos settle and are localized in embryo collector 6 with a small amount of washing liquid to maintain their viability. The flushing fluid filtered through the embryo-collector 6 through the nozzle connecting the embryo-collector 6 with a capacity of 1 through the return opening 3 of the base 2 is returned to the container 1, from which the flushing fluid is continuously taken due to the operation of the patented installation, which ensures the continuity of the circulations of flushing fluid. During the entire procedure for washing the embryos, the pneumatic 4-hole, made open, ensures the regulation of the internal air pressure in the tank.

The duration of the entire washing procedure is 3-5 minutes, after which the electronic control unit 27 is turned off and the pump 13 stops its operation. The operator under rectogenital control performs a light massage of the uterine horn, which helps to remove the flushing fluid from the uterine horn through the channel 22 of the three-channel catheter 20. After that, the pipelines 25 and 26 connecting the three-channel catheter 20 with the unit are disconnected from it, including the syringe 24 from the channel 23 and air is removed from the inflatable balloon 28. The three-channel catheter 20 is removed from the uterine horn cavity, and the procedure for washing the embryos from one uterine horn is completed. If necessary, washing the second horn of the uterus, the procedure for washing the embryos is carried out similarly.

After completing the entire procedure for washing out the embryos from the filter unit 10, the embryo collector 6 is disconnected from the base 2, which, in addition, serves as a container for storing and transporting the embryos, and sent to the laboratory for morphological evaluation of the obtained embryos.

A patented device used in biotechnological methods for the accelerated reproduction of farm animals, in particular, in the technology of multiple ovulation and embryo transplantation, using systems for non-surgical extraction of closed-loop embryos, increases the collection of embryos due to the fact that excludes breaks between cycles of washing fluid during the procedure leaching embryos from the uterus of the animal. It ensures the continuity of the circulation cycles of the washing fluid in the closed loop of the system due to the automated injection of the washing fluid by the pump 5 and the continuous outflow of the washing fluid together with the embryos from the uterine horn of the animal.

The design of the patented device, connected to the elements of the system, allows the system to be more compact due to the lack of a network of pipelines and a syringe located at a considerable spatial distance from the container without fixing the syringe body, which are characterized by well-known technical solutions-analogues. The compact-assembled system can be placed in the operator’s working pocket and brought into operation due to the electronic control unit 9.

The design of the patented device allows you to minimize the technological actions of the operator during the operation of the system and contributes to his individual work without the involvement of assistants due to the lack of manipulation of the numerous clamps, valves and tees on the pipelines, which are characterized by well-known technical solutions-analogues.

In addition, the continuity of the circulation cycles of the washing fluid in the closed loop of the system, obtained using the patented device, ensures that the temperature of the washing fluid is constant at the temperature of the uterus of the animal by repeatedly passing the washing fluid through the reproductive tract of the animal, which helps preserve the viability of the embryos during washing .

The duration of the entire leaching procedure using the patented device in the system, which is 3-5 minutes per animal, in contrast to the known analogues, which take 20 to 30 minutes to use this procedure for washing the embryos, allows the entire procedure to be carried out during the duration of the action anesthesia in an animal. At the same time, the sensitivity of the animal to rectal manipulations and to the presence of a catheter in the uterus is reduced, the risks of uterine contraction and irritation of its mucous membrane, bleeding in the uterus and rectum of the animal are excluded, which, in general, increases the efficiency of obtaining more embryos.

An additional aspect of the use of a patentable utility model is the reorganization of the uterus of an animal in order to treat post-natal complications, in particular endometritis.

The patented device was manufactured by the Federal State Budget Scientific Institution “Center for Experimental Embryology and Reproductive Biotechnologies” (FGBNU TSEERB) and tested on cows and heifers in a number of farms in the Moscow region. The results obtained indicate that the patented device increases the rate of embryo collection during the procedure for washing the embryos.

A patented device can be manufactured industrially.

Claims (1)

Installation for non-surgical extraction of embryos in animals, including a container designed to accommodate flushing fluid with a base mounted on the container, in which a return, pneumatic and intake opening are made, and the container is connected to the embryo collector through the return opening using the nozzle provided with the embryo collector , the pneumatic adjustment hole is made open with the possibility of regulating the internal air pressure in the tank, characterized in that the base on its outer side, along its entire perimeter, has a side wall forming a chamber together with the base, on the outer side of which, in addition, partitions are installed that divide this chamber into filter, intake-discharge and battery blocks, while the return and pneumatic adjustment openings are made at the base at the location of the filter unit, the intake hole is made at the base at the location of the intake-pumping unit, in addition, at the intake hole of the intake-pumping unit a suction and discharge element is installed on the unit in the form of a pump with an intake and discharge nozzles, configured to create an adjustable pressure gradient when the washing fluid moves, while the intake and discharge element is attached to the base due to the intake nozzle installed in the intake opening so that the lower open end of the intake pipe is located under the base inside the tank, in addition, the intake-discharge and battery units are closed by a lid with a hole in it Thieme established in location-intaking discharge unit, wherein the hole in the nipple is set, for connection with the discharge pipe, in addition, the battery pack installed power supply unit connected to the intake-discharge member.

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