RU2778066C1 - Perfusion pump for pumping blood - Google Patents

Abstract

FIELD: medical technology.

SUBSTANCE: invention relates to medical technology. The perfusion pump for pumping blood includes a housing with inlet and outlet pipes equipped with valves and an elastic membrane. The housing cover is equipped with a channel for connecting a vacuum pump. The additional chamber is adjacent to the outer surface of the housing and is equipped with an additional elastic membrane. The housing is made in the form of a sealed body of rotation with the possibility of creating an adjustable amount of discharge in it. A rotor with a recess and a channel for creating a vacuum in the recess is installed inside the housing. The elastic membrane is located in the gap between the housing and the rotor and is made with diametrically oppositely spaced internal cavities that form working chambers when interacting with the recess of the rotor. The inlet pipe is mounted on an additional chamber equipped with an additional elastic membrane fixed on the inner surface of the additional chamber and dividing the additional chamber into two cavities, one of which, formed by the walls of the additional chamber and an additional elastic membrane, is connected to one cavity of an elastic membrane located in the gap between the rotor and the other forms the inner space of the additional chamber and is communicated through a valve with a second cavity of an elastic membrane located in the gap between the rotor and the housing. The second cavity of the elastic membrane is connected to the outlet pipe.

EFFECT: reducing the mechanical effects on the blood.

1 cl, 2 dwg

Description

The invention relates to medical equipment, namely to pumps for pumping blood - perfusion pumps, and can be used to organize cardiopulmonary bypass - perfusion in cardiac prosthetics - to create an artificial heart.

Known peristaltic pump intended for use in heart-lung machines (perfusion pump), containing a stator with a movable working element and an elastic tube adjacent to its inner surface, placed in the stator cavity, and on the drive shaft there is a rotor with rollers mounted on axes with the possibility contact with an elastic tube, where the movable working element is installed with the possibility of reciprocating movement in the direction perpendicular to the axis of rotation of the rotor, and is pivotally connected to one end of the connecting rod, the other end of which is pivotally connected to the latch crank mounted on the axis with the possibility of rotation relative to the wall pump housing, and the occlusion control mechanism ( Occlusion (eng. occlusion from Latin occlusio "concealment") is a term that indicates any state that is usually open, but at a certain point in time is completely closed.) is made in the form of an adjustable eccentric stop, size still in the housing with the possibility of contact with the other end of the connecting rod below a straight line connecting the center of the axis of the crank-latch with the center of the hinge connection of the connecting rod with a movable working element [1].

The well-known peristaltic pump is intended for use in cardiopulmonary bypass devices, however, periodic compression of the elastic tube by the rollers of the rotor, especially when the moving working element is in the closest position to the rotor, entails the risk of hemolysis - blood injury with partial destruction of erythrocytes [2], that is, does not provide "sparing" mode of transportation of this substance. Taking into account the fact that during cardiopulmonary bypass the blood must repeatedly pass through this pump, this effect is enhanced, which ultimately leads to an unacceptable deterioration in its structure.

It is also known a device for pumping blood - a perfusion pump (artificial heart), chosen by us as a prototype, including a body equipped with pipes, valves and divided by a membrane into a blood chamber and a working chamber, while on the inner surface of the blood chamber, horn-shaped recesses are made to swirl the blood flow in the direction of the outlet valve, and the frames of artificial inlet and outlet valves with disc locking elements are installed in the body branch pipes [3].

In a known device, the separating membrane is driven using a pneumatic system (not described in the prototype), which in its complexity will be significantly higher than the proposed device, since reliable switching elements that switch gas flows and an appropriate control system for these elements are required. Moreover, the adjustment of the volume of pumped blood and the frequency of operation of the proposed device are also related to the capabilities of the pneumatic system used, which significantly increases its complexity and, accordingly, reduces reliability.

The aim of the present invention is to improve the reliability and simplify the device.

The problem is solved due to the fact that in a known device for pumping blood - a perfusion pump (artificial heart), including a housing with inlet and outlet pipes equipped with valves, an elastic membrane that interacts with a pneumatic drive and forms a working chamber and a chamber for blood, the body is made in the form of a hermetic body of rotation with the possibility of creating an adjustable amount of vacuum in it, inside which a rotor with one or more shaped recesses is installed, and an elastic membrane is placed in the gap between the housing and the rotor and is made with diametrically opposite internal cavities, which form, when interacting with the recess ( grooves) of the rotor of the working chamber, while the inlet pipe is mounted on an additional chamber adjacent to the outer surface of the housing, and equipped with an additional elastic membrane fixed on its inner surface and dividing the latter into two cavities - one of which is formed wall of the additional chamber and the membrane, communicates with one of the cavities of the elastic membrane located in the gap between the rotor and the housing, and the other forms the internal space of the additional chamber and communicates through the valve with the second cavity of the elastic membrane located in the gap between the rotor and the housing, which in turn communicates with the outlet pipe.

The essence of the invention lies in the fact that the body is made in the form of a sealed body of rotation. This form of housing is the most technologically advanced in the manufacture and operation of the device, and also simplifies the design and installation of other elements placed in the housing.

The possibility of creating a housing, and consequently, in the recess of the rotor, adjustable vacuum (vacuum) allows you to change the force of interaction between the rotor, or rather, between the recess (recesses) of the rotor, and an elastic membrane without any mechanical devices, which simplifies the device when maintaining the ability to control its performance.

Placement inside the hermetic housing of the rotor with one or more shaped recess allows you to form, at the selected value of vacuum (vacuum), inside the recess of the rotor, the corresponding deformation of the elastic membrane necessary for peristaltic pumping of blood without unacceptable effects on both the blood and the membrane, which increases reliability devices. If there are several recesses on the rotor, it is possible, at a constant rotational speed of the latter, to increase the cyclic frequency (pulse) of the device operation by a multiple of the number of recesses.

The placement of an elastic membrane, which is made with diametrically opposite internal cavities, in the gap between the housing and the rotor allows active interaction of the recess (recesses) of the rotor with the membrane, thus forming working chambers, which are elements of the pumping system. At the same time, diametrically opposite membrane cavities functionally divide the latter into a "suction" cavity and a "pressure" cavity, which simplifies the design of the device without the use of additional means of dividing flows.

The use of an additional chamber adjacent to the outer surface of the housing makes it possible to form a "portion" of blood sucked through the inlet pipe mounted on the additional chamber.

The presence of an additional elastic membrane fixed on the inner surface of the additional chamber allows the latter to be divided into two cavities - one of which, formed by the walls of the additional chamber and the membrane, communicates with one of the cavities of the elastic membrane located in the gap between the rotor and the housing, thus forming " suction" part of the pumping system, and the other one forms the internal space of the additional chamber and communicates through the valve with the second cavity of the elastic membrane located in the gap between the rotor and the housing, thereby creating a "pumping" part of the overall pumping system, synchronized by the rotating rotor of the device. At the same time, through the outlet pipe, which communicates with the “pumping” part of such a pumping system, a pulsating blood supply is carried out, the one-time volume of which is determined by the degree of vacuum in the internal space of the rotor recess, and the pulsation frequency is determined by the rotational speed of the rotor of the device.

The invention is illustrated by drawings.

For example, the shape of the housing in this description is assumed to be cylindrical, although the housing can be made in the form of any body of revolution.

Figure 1a, b schematically shows the general view of the proposed device in sections in the absence of vacuum inside the case.

Fig. 2 a, b, c, d shows the section C-C according to Fig. 1a in various phases of the operation of the proposed perfusion pump in the presence of reduced pressure in the housing.

The proposed perfusion pump (artificial heart) (see Fig. 1a,b) consists of a sealed housing 1, inside which is placed a rotor 2 with a shaped recess 3 (hereinafter we are talking about one recess). In the gap between the rotor 2 and the inner surface of the housing 1, an elastic membrane 4 is installed with diametrically located internal cavities 5 and 6. An additional chamber 7 with an inlet pipe 8 adjoins the side surface of the housing 1. An additional membrane 9 is placed inside the additional chamber 7, separating the additional chamber 7 into two cavities 10 and 11. The first of them (10) communicates through channel 12 with cavity 6 of membrane 4, and the second (11) through valve 13 with cavity 5 of membrane 4, which in turn communicates with outlet pipe 14. 8 and outlet 14 pipes are equipped with valves 15 and 16. In the cover 17 of the housing 1, a channel 18 is made for connecting a vacuum pump (not shown in the figures), which creates a given vacuum inside the housing 1, and therefore, inside the recess of the housing 3. Channel 19, made in the body of the rotor 2 improves the conditions for creating a vacuum inside the recess 3 during operation of the device. On the bottom cover 20 of the housing 1, an electric motor 21 is mounted, which is the drive of the rotor 2.

The proposed perfusion pump works as follows. It is assumed that before the start of work, the pressures in all its cavities are equal, for example, to atmospheric pressure, and the rotor rotates counterclockwise with a given frequency. Air is pumped out through channel 18 to create the required vacuum inside housing 1, and, consequently, in recess 3 of rotor 2 through channel 19 (see Fig. 1). In this case, a pressure difference arises between the internal cavities 5,6 of the elastic membrane 4 and the recess 3 of the rotor 2. Due to the pressure difference that has arisen in this way, the walls of the elastic membrane 4 adjacent to the recess 3 of the rotor 2 begin to deform (see Fig. 2), trying to fill the recess 3. At the position of the rotor 2, shown in Fig. 2a, the volume of the cavity 6 of the elastic membrane 4 increases sharply. The pressure in the cavity 6 decreases, which leads to a decrease in pressure in the cavity 10 between the additional membrane 9 and the inner walls of the additional chamber 7, since the cavity 10 communicates through the channel 12 with the cavity 6. The additional membrane 9 tends to "stick" to the walls of the additional chamber 7, increasing thus the volume of the cavity 11, where the pressure also drops. In this case, the valve 15 in the inlet pipe opens, and the valve 13 separating the cavities 11 and 5 closes. The cavity 11 is filled with blood through the inlet 8 and valve 15.

As the rotor 2 turns further counterclockwise (see Fig. 2b), the resulting swelling (deformed area) of the cavity 6 of the membrane 4 is “squeezed out” at the boundary of the cavities 6 and 5. At the same time, the pressure in the cavity 6 increases, and consequently, the pressure increases and in the cavity 10, which communicates with the cavity 6 channel 12. Additional membrane 9 begins to take its original position. However, the recess 3 of the rotor 2 begins to interact with the wall of the cavity 5 of the membrane 4, which, by deforming, increases the volume of the cavity 5, reducing the pressure in it. At the same time, blood flows intensively through valve 13 from the cavity 11 of the additional chamber 7 into the increased volume of the cavity 5. Since the pressure in the cavity 5 is reduced, the valve 16 in the outlet pipe 14 is in the closed state, and “feeding” occurs through the valve 15 of the inlet pipe 8 cavity 11 with blood.

With further movement of the rotor 2 (counterclockwise) (see Fig. 2c), the increased volume of the cavity 5 of the membrane 4 is completely filled with blood. The pressure in the cavities 5 and 11 stabilizes and becomes equal to atmospheric pressure. The flow of blood into the cavity 11 through the inlet 8 stops. At this stage, a portion of blood is transported by the deformed cavity 5 to the outlet pipe 14.

When the recess 3 of the rotor 2 approaches the outlet pipe 14 (see Fig. 2 d), a portion of blood is “squeezed out” from the resulting swelling of the wall of the cavity 5 into the outlet pipe 14. The pressure in the cavity 5 increases, the valve 13 closes, and the valve 16 of the outlet pipe 14 opens. A portion of the blood enters the circulatory system.

Further rotation of the rotor 2 leads to a repetition of the entire cycle of the pump.

A feature of the proposed device is that at any position of the rotor 2 and at any degree of pressure reduction in the cavity 3 of the rotor 2, there are no unacceptable mechanical effects on the blood, which guarantees the safety of its components during multiple circulation cycles. In addition, by changing the speed of rotation of the rotor 2 and the degree of pressure reduction in the cavity 3 of the rotor 2, during the operation of the device, it is possible to easily change the rhythm of the supply and the single volume of blood pumping, which makes it possible to quickly adjust the parameters of the circulatory system over a wide range.

Sources of information

1. Patent RU 2017502, Peristaltic pump (Analogue).

2. Urazbakhtin R.R., Vavilov V.E. Artificial heart and artificial heart ventricles // Modern scientific research and innovations. 2017. No. 2 [Electronic resource]. URL: https://web.snauka.ru/issues/2017/02/78875.

3. Patent RU 127315, Device for pumping blood (artificial heart) (Prototype).

Claims (1)

Perfusion pump for pumping blood, including a housing with inlet and outlet fittings equipped with valves, and an elastic membrane, characterized in that it contains a housing cover with a channel for connecting a vacuum pump and an additional chamber adjacent to the outer surface of the housing and equipped with an additional elastic membrane, housing made in the form of a sealed body of rotation with the possibility of creating an adjustable amount of vacuum in it, a rotor with a recess and a channel for creating a vacuum in the recess is installed inside the housing, an elastic membrane is placed in the gap between the housing and the rotor and is made with diametrically opposite internal cavities that form during interaction working chambers with a recessed rotor, while the inlet pipe is mounted on an additional chamber equipped with an additional elastic membrane fixed on the inner surface of the additional chamber and dividing the additional chamber into two cavities, one of which, formed by the walls of the additional chamber and an additional elastic membrane, communicates with one cavity of the elastic membrane located in the gap between the rotor and the housing, the other forms the internal space of the additional chamber and communicates through the valve with the second cavity of the elastic membrane located in the gap between the rotor and the housing, and the second cavity of the elastic membrane communicates with the outlet pipe.

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