RU160215U1 - THREE-CHANNEL CATHETER INTENDED FOR NON-SURGICAL EXTRACTION OF EMBRYOS IN ANIMALS, WITH A SPIRAL DISTAL END OF THE DELIVERY CHANNEL - Google Patents

Abstract

A three-channel catheter designed for non-surgical extraction of embryos in animals, with a spiral distal end of the delivery channel, containing a tube with perforations with three isolated channels made inside it, one of which is an air channel designed to pass air through it, the second channel is a supply channel, intended for introducing the washing fluid into the cavity of the uterine horn of the animal, and the third channel is the outlet channel designed to remove from the cavity and the uterus of the washing fluid containing leachable embryos, wherein the air channel is connected to the inner cavity of the inflatable balloon located and fixed externally to the tube near its distal end, the air channel being connected to the inner cavity of the inflatable balloon through an opening made in the wall of the air channel at the location of the inner middle part of the inflatable balloon, in addition, a tip is attached to the distal end of the tube, and the proximal end of the tube is made in the form of a connector s dividing the above three channels with each other for separate access to each of these channels, while the air channel connector is a discharge-air connector, the supply channel connector is a supply connector, the output channel connector is an output connector, characterized in that the tip is made in one piece a recess in its central part, made from the side of the distal end of the tube attached to the tip, in addition, in the portion of the tube between the inflatable balloon and the tip, the distal end along giving ka

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.

Known three-channel catheter for non-surgical extraction of embryos from Minitube International, Germany (Animal reproduction technology. Cattle. Website: www.minitube.de, 2015), containing a tube with perforations and channels made inside it: air, feed and lead out. The air channel contains an air cylinder, which is located on the tube near its distal end and is fixed on its outer side. An opening is made in the wall of the air channel that connects the internal cavity of the air channel with the internal cavity of the inflatable balloon. The distal end of the tube ends with a hollow tip, and from the proximal end of the tube is made in the form of connectors that share these three channels.

There is a three-way Foley catheter used in non-surgical embryo extraction technology, the design of which is similar to the one described above (Internet Sites: http://selo-delo.ru/zhivotnovodstvo-promysly/38-tekhnologii-polucheniya-i-sokhraneniya-telyat-transplantatsiya-embrionov- besplodie-zhivotnykh-i-mery-profilaktiki? start = 3, 2015; http://www.apexmed.ru/catalogue/kateter-foleya-trehhodovoj-apexmed.html, 2015)

Known three-channel catheter (prototype - VV Madison, VL Madison. Transplantation of embryos in the practice of breeding dairy cattle. - M: IN "Agropromizdat", 1988, p. 67-71), which is a tube and three isolated channels made inside it, one of which is an air channel designed to allow air to pass through it, the second channel is used to introduce flushing fluid into the uterine horn cavity (delivery channel), and the third channel is used to flush flushing fluid from the uterine cavity, containing vym called embryos (excretory channel). In this case, the air channel is connected to the inner cavity of the inflatable balloon through an opening made in the wall of the air channel at the location of the inner middle part of the inflatable balloon, which is located and attached near the distal end of the tube from its outer side. In addition, a hollow plastic cannula (tip) with 2 side holes is attached to the distal end of the tube, while one of these holes is connected to the delivery channel, and the other hole to the catheter exit channel. The proximal end of the tube is made in the form of connectors that divide the above three channels between each other for separate access to each of them in order to connect with any of the devices used as auxiliary tools during the procedure for extracting embryos from animals (pipelines, syringe for air supply syringe for supplying flushing fluid, mandrels (stilettos), etc.). At the same time, the connector of the air channel is the discharge-air connector, the connector of the supply channel is the supply connector, the connector of the output channel is the output connector.

The procedure for extracting embryos using the prototype device is that the operator inserts a three-channel catheter into one of the uterine horns of an animal, for example, a cow, and a stylet (mandrin), which is an auxiliary tool, is preliminarily inserted to stiffen the three-channel catheter when it passing through the cervix and bifurcation of the horns of the uterus of the animal. In this case, the distal end of the stylet abuts against the inner wall of the hollow tip. After the catheter passes through the cervix and the bifurcation of the uterine horns of the animal, the stylet is removed. A rectogenital examination of the fixation site of the catheter in the uterine horn is performed and, using a syringe to supply air through the air channel of this catheter, an inflatable balloon is filled with air, which in its expanded form covers the cavity of the uterine horn, reliably fixing the three-channel catheter. Then, appropriate equipment is connected to the connectors of this catheter, for example, which are parts of the system for non-surgical extraction of embryos, which is a container with washing liquid connected in series via pipelines, a device for collecting and localizing embryos (embryo collector), and a syringe designed to be sucked through flushing fluid pipelines from the reservoir and for supplying this fluid through pipelines to the uterine cavity, a syringe for supplying air to the catheter.

Analogs and prototype have common disadvantages, which are that:

- the maneuverability of a catheter reinforced with a stylet, the end of which is located in the hollow tip of this catheter, is complicated when the animal’s reproductive tract is obstructed by the anatomical structure of the inner walls of the animal’s cervix in the form of bends and bulges (longitudinal and transverse folds of the cervical canal, post-traumatic and post-genital adhesions and etc.), contributing to the distortions of the hollow tip, which can abut against the inner wall of the cervix and injure its mucous membrane, th bleeding; due to the density of the tissue of the cervix, it is impossible to determine the rectal location of the tip, while the operator, who does not see the skew of the tip, continues to advance the catheter further into the cavity of the cervix, exacerbating injuries leading to even greater complications; after the injury, the blood enters with the catheter at the top of the uterine horn, adversely affecting the viability of the embryos; in addition, due to blood coagulation, embryos adhering to it will not be found after extraction, which, in general, reduces embryo collection;

- when filling an inflatable balloon with air, which in a straight form should overlap the uterine horn cavity and limit for the purpose of washing the embryos its portion in which they are located (hereinafter - the limited area) due to the anatomical features of the reproductive organs of each animal (age, physiological factors , the presence of pathological processes), it is difficult to stabilize the pressure of the injected air into the inflatable balloon 5; if the inflatable balloon is insufficiently filled with air, the flushing fluid together with the embryos may leak out of the limited area beyond the borders of the inflatable balloon, and if there is an excess of air, this balloon may burst or slip out of the uterine horn together with the catheter during accumulation of flushing fluid in this limited area and / or when the operator conducts mandatory massage manipulations with the uterine horn; as a result, this can lead to loss of embryos;

- when the flushing fluid is supplied through the catheter’s feed connector, the pressure of the flushing fluid supplied cannot be adjusted due to the prototype catheter’s design, which leads to hydraulic shock of the flushing fluid on the embryos adjacent to the uterine endometrium, which can be displaced either to the top of the uterine horn, or between the inflatable balloon and the uterine wall in contact with it, and, as a result, the embryos become inaccessible for extraction;

- due to the peculiarities of the anatomical structure of the uterine horn of the animal, expressed by its bend, the inserted catheter during the filling of the inflatable balloon with air can fit snugly against the inner wall of the uterine horn, which blocks the outlet of the washing fluid from the openings of the delivery channel, and, as a result, the embryos from this The site of the uterine horn cannot be extracted.

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

The technical result of the utility model is to increase the collection of embryos in animals.

The technical result is achieved by the fact that a three-channel catheter, designed for non-surgical extraction of embryos in animals, with a spiral distal end of the supply channel contains a tube 1 with perforations with three isolated channels made inside it, one of which is an air channel 2, designed to pass air through it , the second channel is a supply channel 3, designed to introduce flushing fluid into the cavity of the uterine horn of the animal, and the third channel is the output channel 4, designed to remove washing fluid containing leachable embryos from the uterine cavity, while the air channel 2 is connected to the inner cavity of an inflatable balloon 5 located and fixed from the outside to the tube 1 near its distal end, and the air channel 2 is connected to the inner cavity 12 of the inflatable balloon 5 through an opening 7 made in the wall of the air channel 2 at the location of the inner middle part of the inflatable balloon 5, in addition, the tilt is connected to the distal end of the tube 1 6, and the proximal end of the tube 1 is made in the form of connectors that separate the above three channels between each other for separate access to each of these channels, while the air channel connector is a discharge-air connector 8, the feed channel connector is a supply connector 9, connector the output channel 4 is a terminal connector 10, in which, according to a utility model, the tip 6 is made monolithic with a recess 11 in its central part, made from the side of the distal end of the tube 1 connected to the tip 6, moreover, in the portion of the tube 1 between the inflatable balloon 5 and the tip 6, the distal end of the supply channel 3 is made spiral, in addition, in the same portion of the tube 1 between the inflatable balloon 5 and the tip 6, the outlet openings 13 are made in the outer wall of the feed channel 3, and in the outer the wall of the outlet channel 4 has intake openings 14, in addition, the supply connector 9 is equipped with a stabilizing-regulating tank 16, and the discharge-air connector 8 is equipped with a pneumatic-regulating tank 15.

The figure shows a three-channel catheter designed for non-surgical extraction of embryos in animals, with a spiral distal end of the delivery channel (hereinafter referred to as the catheter, patented device), general view.

Patented device operates as follows. The principle of operation of the catheter is one and the same, regardless of the equipment used, used in various technologies for the extraction of embryos in animals (methods of gravity flow, extrusion, closed loop, etc.).

Prior to the embryo extraction procedure, in which the catheter is to be introduced into the reproductive organs of the animal, it is prepared for work with a preliminary check of the integrity of the inflatable balloon 5. For this, an auxiliary tool is connected to the air channel 2 through the air-injection connector 8 - a syringe with the syringe inserted into it air volume, for example 15-20 cm ³ and pressing the plunger of the syringe is introduced air which enters through the opening 7 into the inner cavity 12 of the inflatable balloon 5. after confirming that the offline on reducing the integrity of the inflatable balloon 5, the syringe is disconnected and air is removed from this balloon due to the fact that the catheter must be inserted into the uterine cavity of the animal when the inflatable balloon is empty 5. Preparation of the catheter for work is completed by the fact that the syringe with the air drawn into it is reconnected to the air channel 2 through the discharge-air connector 8, and in the output channel 4 through the output connector 10 enter the stylet (mandrin), which is also an auxiliary tool for stiffening (to strengthen) the catheter when it is inserted and the horn of an animal uterus. At the same time, the distal end of the stylet is carried out all the way into the recess 11, made in the Central part of the tip 6.

Immediately prior to washing the embryos from donors, the animal is fixed in the machine and preparatory procedures are performed: 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.

The procedure for embryo extraction begins with the introduction of a patented device prepared for work as described above, into the reproductive tract of the animal, while the distal end of the tube 1 with tip 6 is carried out using a stylet that reinforces the catheter through the vagina and cervix of the animal, and the catheter is further advanced to its introduction into one of the uterine horns.

The execution of the tip 6 monolithic, in comparison with the known similar catheters in which such a tip is hollow, eliminates the distortion of the tip when exposed to the stylet while moving along the bends and bulges of the inner wall of the cervix of the animal, reducing the risk of damage to the tissues of the animal's reproductive organs. In addition, the distal end of the stylet has the ability to maneuver in the recess 11 of the tip 6 at the moments of advancement of the tube 1 with the tip 6 along the bends and bulges of the inner wall of the cervix of the animal, and the tip 6, in turn, when the stylet is exposed to it from the recess 11 (i.e., from the proximal side of the tip 6), maneuvers with its distal end when passing anatomical obstacles in the cervix of the animal, minimizing injuries. In General, the tip 6, made monolithic with a recess 11 in its central part, designed to accommodate the distal end of the stylet in it with the stop, allows you to increase the catheter’s maneuverability when moving it inside the animal’s reproductive organs and, as a result, increase embryo collection by preventing bleeding that reduce the number of embryos received.

The catheter is advanced deep into one of the horns of the uterus of the animal 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 in the uterus. When the distal end of the catheter reaches the location in the internal cavity of the uterine horn, which is determined by the operator, air is injected into the inflatable balloon 5 through a delivery-air connector 8 of the air channel 2, which in a straightened form covers the cavity of the uterine horn, reliably fixing the catheter. At the same time, that part of the uterine horn cavity that is bounded by the walls of the uterine horn apex and the inflatable balloon 5 filled with air is the place for optimal extraction of embryos (hereinafter - the limited uterine cavity).

The pneumatic control tank 15, which is equipped with a discharge-air connector 8, allows you to stabilize the air pressure when it enters the inflatable balloon 5 through the air channel 2, as well as when the operator accidentally presses the inflatable balloon 5, or when excess rinsing liquid is used, it reduces the compression of the inflatable balloon cylinder 5, while maintaining its integrity.

After the catheter is fixed in the uterine horn cavity, the stylet is removed from the catheter.

A catheter fixed in the internal cavity of the uterine horn is connected to the corresponding auxiliary instruments used to extract the embryos. At the same time, a blower (for example, a syringe) with a washing liquid is connected to the supply connector 9, through which embryos from the uterus of the animal will be washed. A conduit used to divert from the catheter, namely from its outlet channel 4, the flushing fluid with the extracted embryos, is connected to the output connector 10.

The flushing fluid is fed into the catheter by means of a supercharger through the supply connector 9, equipped with a stabilizing-regulating reservoir 16, from which it enters the supply channel 3, intended for introducing the flushing fluid into the cavity of the uterus of the animal. At the same time, the stabilizing and regulating tank 16 allows you to stabilize the pressure gradient when the washing fluid enters and moves at the junction of the supercharger with the feed connector 9 and along the entire length of the feed channel 3.

The stabilizing and regulating reservoir 16, in comparison with the known similar catheters in which such a structural element is absent, helps to increase the collection of embryos in the process of their extraction. Depending on the washing methods used, for example, when manually applying pressure to the syringe plunger (rinsing liquid supercharger), from which rinsing liquid is introduced into the catheter through the supply connector 9 of the patented device, due to the increased cross section of the stabilizing-regulating tank 16 compared to the cross section of the supply connector 9, creates a difference in cross-sectional area. In this regard, the concentration of the flushing fluid in the stabilizing-regulating tank 16, which leads to a decrease in the speed of the supplied flushing fluid and to increase its pressure in the stabilizing-regulating tank 16. From this tank 16, the flushing fluid flows further through the supplying connector 9 to the supply channel 3. Moreover, a narrower cross-section of the supply connector 9 compared with the cross-section of the stabilizing-regulating tank 16 helps to reduce the compression of the washing fluid, an increase in the growth rate of its passage, and, as a result, in accordance with Bernoulli’s law, to a decrease in its pressure, which allows a flushing fluid to give a constant pressure gradient when passing through the supply connector 9 and the supply channel 3. Thus, the stabilizing-regulating tank 16 stabilizes then the pressure of the washing liquid, which is necessary for a given section of the supply channel 3 and forms a constant pressure gradient during the movement of the washing liquid along the entire length of the supply channel 3.

After passing through the supply channel 3, the flushing fluid through its outlet openings 13 enters that part of the uterine horn cavity, which is bounded by the walls of the uterine horn apex and the inflatable balloon 5 filled with air, being a place for optimal extraction of embryos (limited uterine cavity). Upon receipt of the flushing fluid with a constant pressure gradient created using the stabilizing-regulating reservoir 16, uniform washing of the walls of the uterine horn occurs, while the embryos are washed off, uniformly and simultaneously lifted from the uterine endometrium. As the flushing fluid enters through the supply channel 3, the limited uterine cavity is filled, and an excess fluid pressure is created in it, which facilitates the entry of this flushing fluid together with the embryos into the outlet channel 4 of the tube 1 through the intake openings 14. Through the outlet channel 4, the washing fluid together with the embryos makes an outflow towards the outlet connector 10, to which a pipeline is connected, through which the washing liquid with the extracted embryos enters, for example, into the container for collecting embryos Whether a device for localization of embryos derived from genital animals during treatment washout of embryos in female donors (embriosbornik, embriofiltr). After the entire volume of fluid intended for washing one horn of the uterus has been used up, the operator performs rectal palpation massage manipulations with this horn of the uterus to drain the residual flushing fluid from the limited uterine cavity and the embryo extraction procedure is completed.

The implementation of the outlet openings 13 in the outer wall of the supply channel 3 on the tube 1 between the inflatable balloon 5 and the tip 6 increases embryo collection due to the fact that the flushing fluid leaves the uterine cavity and, without causing a hydraulic shock, uniformly washes the walls of the uterine horn and at the same time flushes all available embryos from them. The implementation of the sampling holes 14 in the wall of the outlet channel 4 on the tube 1 between the inflatable balloon 5 and the tip 6 increases embryo collection due to the fact that the accumulated flushing fluid in the limited uterine cavity with the embryos inside it, evenly flows into the outlet 4 under its excess pressure , not allowing floating embryos to settle on the inner walls of the uterine horn. The outlet openings 13, as well as the intake openings 14 in the manufacture of the patented device, can be made in a preferred amount from 3 to 10. Such a number of holes, as practice shows, allows you to create the optimal flow of flushing fluid into a limited uterine cavity, as well as the optimal outflow of flushing fluid with embryos.

Performing the distal end of the supply channel 3 spiral in the portion of the tube 1 between the inflatable balloon 5 and the tip 6, increases embryo collection due to the fact that the output of the washing fluid from the supply channel 3 into the limited uterine cavity is carried out from its outlet openings 13 around the entire circumference of the tube 1, as much as possible washing the inner walls of the uterine horn and contributing to the most complete extraction of embryos.

If it is necessary to wash the embryos from the contralateral horn of the uterus, air is removed from the inflatable balloon 5, the catheter is removed from the cavity of the washed uterine horn until it reaches the distal end of the bifurcation line, the pipeline used as an auxiliary tool for removal from the catheter is disconnected from terminal 10 it is from its outlet channel 4, the washing fluid with the extracted embryos. After that, a syringe with the air drawn into it is connected to the air channel 2, and a stylet (mandrin) is inserted into the output channel 4 through the output connector 10, and then the process of washing the embryos from the contralateral uterine horn is carried out similarly to the method described above.

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 in a number of farms in the Moscow region. The results obtained indicate that the patented device increases the collection of embryos from donor cows.

The proposed utility model is new, since the set of its essential features is not known from the prior art, and also meets the patentability condition “industrial applicability”.

A three-channel catheter designed for non-surgical extraction of embryos in animals with a spiral distal end of the delivery channel can be manufactured industrially.

Claims (1)

A three-channel catheter designed for non-surgical extraction of embryos in animals, with a spiral distal end of the delivery channel, containing a tube with perforations with three isolated channels made inside it, one of which is an air channel designed to pass air through it, the second channel is a supply channel, intended for introducing the washing fluid into the cavity of the uterine horn of the animal, and the third channel is the outlet channel designed to remove from the cavity and the uterus of the washing fluid containing leachable embryos, wherein the air channel is connected to the inner cavity of the inflatable balloon located and fixed externally to the tube near its distal end, the air channel being connected to the inner cavity of the inflatable balloon through an opening made in the wall of the air channel at the location of the inner middle part of the inflatable balloon, in addition, a tip is attached to the distal end of the tube, and the proximal end of the tube is made in the form of a connector s dividing the above three channels with each other for separate access to each of these channels, while the air channel connector is a discharge-air connector, the supply channel connector is a supply connector, the output channel connector is an output connector, characterized in that the tip is made in one piece a recess in its central part, made from the side of the distal end of the tube attached to the tip, in addition, in the portion of the tube between the inflatable balloon and the tip, the distal end along the supply channel is made spiral, in addition, in the same section of the tube between the inflatable balloon and the tip, the outlet openings are made in the outer wall of the supply channel, and intake openings are made in the outer wall of the outlet channel, in addition, the supply connector is equipped with a stabilizing-regulating reservoir, and the injection - The air connector is equipped with a pneumatic control tank.

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