RU2508U1 - PHYSIOLOGICAL SYSTEM OF DETOXICATION OF BIOLOGICAL LIQUID - Google Patents

Abstract

1. The physiological system of detoxification of biological fluid, mainly blood, containing a pumping unit made in the form of an elastic tube with inlet and outlet valves located at the inlet and outlet, and a mass transfer device, the inlet of which is in communication with the outlet valve, and the outlet - with a detoxified biological system the fluid with which the inlet valve inlet is connected, characterized in that it is equipped with containers with flushing solution and heparinized saline, respectively Ohm, sequentially located in the highway with a dropper, a flow regulator, a non-return valve and a fluid movement interrupter, through which the rinse tank is connected to the inlet valve inlet, while the outlet of the non-return valve is connected to the inlet valve inlet, and the dropper inlet is connected to the outlet of the tank with heparinized saline. 2. The system according to claim 1, characterized in that the tank with the washing solution is made in the form of a flask with two fittings located on the opposite ends of it, while one fitting is in communication with the washing solution, and the other with the air. The system according to claim 1, characterized in that the tank with the washing solution is made in the form of an elastic plastic bag. The system according to claim 1, characterized in that the container with the washing solution is made in the form of a bottle with a rubber stopper through which two needles are inserted, by means of the first of which the container with the washing liquid is in communication with the fluid movement interrupter with the possibility of supplying said solution, and the second needle housed in

Description

Physiological system of detoxification of biological fluid.

.

MKI A 61 M 1/10

The utility model relates to medical equipment, namely to physiological systems of detoxification of biological fluid, mainly blood.

Known physiological system of detoxification of biological fluid, mainly blood, containing a pumping unit, made in the form of an elastic tube with inlet and outlet valves located at the inlet and outlet, and a mass transfer device, the inlet of which is in communication with the outlet valve, and the outlet - with a detoxified biological fluid system with which the inlet valve inlet (1) is connected. This implementation of the system allows for single-catheter perfusion due to the separation of the phases of the intake and return of the purified blood.

A disadvantage of the known technical solution described above and adopted as a prototype is that in order to prevent thrombosis of the mass transfer device during perfusion, it is necessary to use a special dispenser, for example, a syringe or roller pump with a control system. In addition, the physiological perfusion system of this device does not provide recirculation flushing of the hemosorbent.

The objective of which the present utility model is directed is to develop a physiological system of detoxification of biological fluid, which provides increased ease of use while simplifying the maintenance technology of the system through the implementation of recirculation washing of hemosorbent and dosed heparin during perfusion.

To achieve the above technical result, the known physiological system of detoxification of biological fluid, mainly blood, containing a pumping unit made in the form of an elastic tube with inlet and outlet valves located at the inlet and outlet, and a mass transfer device, the inlet of which is in communication with the outlet valve, and the output - with a detoxified biological fluid system with which the inlet valve inlet is connected, equipped with tanks with flushing solution and hepa respectively saline solution, sequentially located in the line with a dropper, a flow regulator, a non-return valve, and a fluid movement interrupter, by means of which a tank with a washing solution is in communication with the inlet valve inlet, while the outlet of the non-return valve is in communication with the inlet valve inlet and the dropper inlet is in communication with the output of the container with heparinized saline solution,

In addition, the tank with the washing solution can be made in the form of a flask with two fittings located on the opposite ends of it, with one fitting connected to the washing solution, and the other to the air.

In addition, the container with the washing solution can be made in the form of an elastic plastic bag.

In addition, the tank with the washing solution can be made in the form of a bottle with a rubber stopper through which two needles are inserted, through the first of which the tank with the washing liquid is in communication with the fluid flow interrupter with the possibility of gravity and / or operation of the pumping unit of the said solution, and the second needle is placed in the tank with the possibility of communication of its internal space above the solution with the air.

In addition, it is equipped with an additional container, the volume of which exceeds the volume of a single portion of the pumping unit and located above the level of the washing solution, the latter being made in the form of a bottle with a rubber stopper through which two needles are inserted, through the first of which the capacity of the washing solution is communicated with a fluid flow interrupter with the possibility of supplying the aforementioned solution to the pumping unit, and the second needle is placed in the tank with the possibility of the solution communicating with the internal cavity capacities.

In addition, the container with the washing solution can be made in the form of a bottle with a rubber stopper through which two needles are inserted, through the first of which the container with the washing liquid is in communication with the fluid flow interrupter with the possibility of supplying the solution, and the second needle is placed with the possibility of communication solution with a line, the free end of which is located above the level of the washing solution and is equipped with a clamp.

These signs are essential and interconnected causal relationship with the formation of a set of essential features necessary and sufficient to achieve the specified technical result.

liquid.

In Fig, 2,3,4,5 - options for performing containers with washing solution.

The utility model is illustrated by a specific implementation example, which, however, is not the only possible one, but clearly demonstrates the possibility of achieving a given set of features of a given technical result.

The physiological system of detoxification of biological fluid, mainly blood, contains a pumping unit, the pumping chamber of which is formed by an elastic tube 1 with inlet and outlet valves 2,3. The elastic tube 1 is located between the fixed wall 4 and the movable platform 5 of the pump unit. The pump chamber through line 6 is connected to a mass transfer device made in the form of a sorption column 7, which is connected via line 8 to a filter 9 connected via line 10, tee 11, line 12 and needle 13 to the patient's circulatory system.

Tee 11 through line 14, quartet 15 and line 16 is connected to the inlet valve 2 of the pump unit, thereby closing the main circuit of the movement of blood. For dosage administration of heparin during perfusion, a container 17 with heparinized saline is used, which is a standard bottle with a rubber stopper through which two needles 18 and 19 are inserted, through the first of which the container 17 is in communication with line 20 to allow gravity to move the said solution, and the second needle is placed in the container 17 with the possibility of communication of its internal space above the solution with the air.

The line 20 is connected to the inlet of the dropper 21, which is connected through its outlet through the line 22 with an installed 23 cross-section regulator 23 to the inlet of the check valve 24, which in turn is connected via a quartet 15 to the pumping unit and line 14. A capacity of 25 s is intended for recirculation washing of the hemosorbent washing solution, usually physiological. Capacity 25 can be made in the form of a standard bottle with a rubber stopper at the end, punctured with short and long needles 26 and 27, respectively, for solution and air. Needle 26 through line 28 is connected to quaternary 15. During perfusion Mg1. 28 is blocked by a fluid movement interrupter 29, made, for example, in the form of a surgical clamp, crane, etc.

Figure 2 presents an embodiment of a container for washing solution in the form of a flask 30 with fittings 31.32 located on opposite ends. In another embodiment, the container 25 can be made, in the form of an elastic plastic bag 33 with one fitting 34 (Fig.Z).

Figure 4 shows an embodiment of a container 25 in the form of a standard bottle 35, in which there is a short needle 36 for liquid and a short needle 37 for air, the latter via a line 38 connected to an additional container 39 having a volume larger than the shock volume (single portion) pumping unit. Capacity 39 is located above capacity 35.

Figure 5 presents an embodiment of a container for a washing solution in the form of a standard bottle 40, in which a needle 41 for liquid and a needle 42 for air are inserted through a rubber stopper, with a nozzle with a clip 44 connected to the latter.

The physiological system of detoxification of biological fluid works as follows.

Capacity 17 is filled with heparinized saline, which is a mixture of saline with heparin, in particular 200 ml of saline, 1 ml of heparin. The same solution fills the entire hydraulic system, including line 20, dropper 21, line 22, non-return valve 24, until Thursday 15, after which line 22 is pinched by the cross-section regulator 23 or any other known clamp. From the reservoir 25, the physiological saline, which serves as a flushing solution, flows by gravity to the line 28, quartet 15, line 14, tee 11, to line 12. In this case, the needle 13 located at the end of the line 12 is not yet connected to the patient's circulatory system, and the line 14 is closed, for example by means of a clamp. The pump installation is turned on and the movable platform 5 begins to make reciprocating movements, periodically compressing the elastic tube 1 by pressing it against the fixed wall 4. At the same time, the flushing solution during the diastole of the pump chamber from the tank 25 through line 28, Thursday 15, line 16 and the inlet valve 2 enters the cavity of the tube 1 and then with the systole of the pump chamber through the exhaust valve 3 through line 6 it enters the sorption column 7, displacing downstream air from line 8, filter 9, line 10, tee 1 1 and highway 12.

For recirculation washing of the hemosorbent, the line 12 is blocked, for example, by a clamp (not shown in the drawings). At the same time, the solution from the tank 25 during the diastole of the pump chamber along the line 28, Thursday 15, line 16, through the inlet valve 2 enters the cavity of the elastic tube 1. At this time, the outlet valve 3 is closed and prevents the backflow of the solution. With inlet systole

. .

valve 2 is closed and the solution from the pump chamber through the opened valve 3 along the line 6 enters the sorption column 7 and, passing through a layer of hemosorbent, leaves microparticles of coal in it and then through line 8, filter 9, tee 11, line 14, Thursday 15 , line 28 enters the container 25, displacing the air from it through the needle 27. During the diastole of the pump chamber, air enters the container 25 through the needle 27 into the space above the liquid, the level of which changes.

8, when the flask 30 is used as a container for washing solution, the intake and return of the solution occurs through the lower nozzle 31, and the air moves through the upper nozzle 32.

In the case of using bag 33 as a capacity, the periodic change in the volume of solution in the bag during systole and diastole of the pump chamber is compensated by stretching and compressing the walls of the elastic bag 33.

In addition, it is possible to use a standard bottle 35 with a short needle 37 for air intake as a capacity for washing solution. In order to eliminate solution losses, the needle 37 is connected by a line 38 to a tank 39 located above the tank 35. When the volume of the solution in the tank 35 changes during the systole and diastole of the pump chamber, the solution enters the additional tank 39, the volume of which should be greater than the shock volume of the pump chamber otherwise the solution will spill out.

Figure 5 presents an application of a standard bottle 40 as a container for a washing solution with a short needle 41 for solution and a short needle 42 for air. To prevent spillage of the solution, a nozzle 43 is attached to the needle 42, which is blocked by a clamp 44 during recirculation washing of the hemosorbent.

When changing the volume of the solution in the tank 40, the volume of air above the solution will be compressed during the systole of the pump chamber and expand during its diastole. The most optimal options for the execution of the capacity for the washing solution are the execution of the capacity 25 in the form of a standard bottle with a long needle for air and in the form of an elastic plastic bag with falling walls when the internal volume changes.

After completion of the recirculation washing of the hemosorbent by the interrupter 29, the trunk 28 is closed. The needle is inserted into the vein of the patient’s circulatory system and, after general heparinization, hemosorption begins in accordance with the existing procedure. During hemosorption, the passage section of line 22 is opened with the help of regulator 23 and the necessary rate of outflow of heparinized physiological solution in drops is established for each blood collection cycle during diastole of the pump chamber when the check valve 24 is open. During the systole of the pump chamber, the hydraulic pressure rises throughout the system, which closes valve 24, thereby obstructing the return flow of blood.

The use of this utility model makes it extremely easy to solve the issue of dosed heparin administration in single-catheter hemosorption mode for each blood sampling cycle, using a closed system to recirculate the hemosorbent. With its relatively simple design, the system can be made in a variant for single use. Posted by L)

Information 8

1.naSfeH Veyainbrigany te 1330833, nya. 04 B 43 / ia I99u

2.nasfeHi RF 1ShOi813, nd. A 61 M 1 / 10.1993 g.

I IM And A.F. Davydkin

Claims (6)

1. The physiological system of detoxification of biological fluid, mainly blood, containing a pumping unit made in the form of an elastic tube with inlet and outlet valves located at the inlet and outlet, and a mass transfer device, the inlet of which is in communication with the outlet valve, and the outlet - with a detoxified biological system the fluid with which the inlet valve inlet is connected, characterized in that it is equipped with containers with flushing solution and heparinized saline, respectively Ohm, sequentially located in the highway with a dropper, a flow regulator, a non-return valve and a fluid movement interrupter, through which the rinse tank is connected to the inlet valve inlet, while the outlet of the non-return valve is connected to the inlet valve inlet, and the dropper inlet is connected to the outlet of the tank with heparinized saline.  2. The system according to claim 1, characterized in that the tank with the washing solution is made in the form of a flask with two fittings located on its opposite ends, while one fitting is in communication with the washing solution, and the other with the air.  3. The system according to claim 1, characterized in that the tank with the washing solution is made in the form of an elastic plastic bag.  4. The system according to claim 1, characterized in that the tank with the washing solution is made in the form of a bottle with a rubber stopper through which two needles are inserted, through the first of which the tank with the washing liquid is in communication with the fluid movement interrupter with the possibility of feeding said solution, and the second needle is placed in the tank with the possibility of communication of its internal space above the solution with the air.  5. The system according to p. 1, characterized in that it is equipped with an additional capacity, the volume of which exceeds the volume of a single portion of the pumping unit and located above the level of the washing solution, the latter being made in the form of a bottle with a rubber stopper through which two needles are inserted, by means of the first of which the tank with the washing solution is in communication with the fluid flow interrupter with the possibility of supplying the said solution to the pump unit, and the second needle is placed in the tank with the possibility of the solution communicating with the internal by an additional capacity.  6. The system according to claim 1, characterized in that the container with the washing solution is made in the form of a bottle with a rubber stopper through which two needles are inserted, through the first of which the tank with the washing liquid is in communication with the fluid movement interrupter with the possibility of supplying the said solution, and the second needle is placed in the tank with the possibility of communication of the solution with the line, the free end of which is placed above the level of the washing solution and is equipped with a clamp.