RU68885U1 - STAND FOR RESEARCH OF HEART VALVES - Google Patents

Abstract

The utility model relates to medicine, namely to cardiac surgery, and can be used for biomedical evaluation of materials and the effect of the interaction of the components of heart valves on their final characteristics. The technical result of the utility model is to smooth out the pulsations of the circulating solution and to reduce the size of the bench due to the possibility of regulating the residual pressure. A stand for the study of heart valves is proposed, containing an aortic 1 and atrial 2 test chambers with places for installing the test valves, an electromagnetic pneumatic valve 9 connected by pneumatic lines with a pneumatic actuator 3 of the working fluid flow through these chambers, a compressor 11 and a vacuum pump 12. The stand is equipped with a damping unit and regulating the residual pressure 4, made in the form of a housing with an elastic membrane 24 and an adjusting diaphragm 25, the supramembrane cavity of which is connected by a pneumatic by means of an electromagnetic pneumatic valve 14 with a compressor 15 and a vacuum pump 16, and hydraulic lines with an aortic test chamber 1 and a hydraulic damper-degasser 5, which is connected to the atrial test chamber 2. Control of the parameters of the test bench and its control is carried out using the control panel 20 with blocks processing the incoming information 19 and issuing control signals 21. The damping and regulation of the residual pressure is ensured by the design of the unit and, on the one hand, by the connection of its supranembrane of the space through an electromagnetic air valve 14 with the compressor 15 and vacuum pump 16, and on the other hand - bond submembrane space-damping degasser and through an adjustable diaphragm 25 - with aortic test chamber 1. z.p.f. 1, 2 Fig.

Description

The utility model relates to medicine, namely to cardiac surgery, and can be used for biomedical evaluation of materials and the effect of the interaction of the components of heart valves on their final characteristics.

The problem of developing new prosthetic heart valves is associated with a comprehensive solution of complex biomedical and technical problems, one of which is the study of the hydrodynamic characteristics of the prosthesis in modes that adequately mimic the physiological conditions of their functioning.

A well-known bench for testing the aortic and mitral valves of the heart for throughput and backflow, containing test chambers for the mitral and aortic valves, pressure vessel, pneumatic accumulator, pneumatic actuator, pulse duplicator, three-position valve, measuring tanks, pressure pipes, float and check valves connecting lines (GOST 26997-86. Artificial heart valves. General specifications. - M .: USSR State Committee for Standards, 1986. - P.24-26).

The main disadvantages of the known device are:

rigid fixation of the valves does not allow recording characteristics in a wide range due to the inability to increase the bore diameter in the systole phase;

rigid square walls of the test chambers and stepped transitions of hydraulic lines significantly increase resistance to fluid flow, which requires non-physiological pressures in the accumulator and reduces the flow characteristics of the tested valves;

the absence of a mechanism that mimics the "systole" of the atrium for the mitral position does not allow to obtain an adequate pressure curve throughout the cycle;

the inability to create conditions that mimic the tricuspid position of the heart valve;

lack of adjustable peripheral resistance, etc.

These shortcomings in the design of the well-known stand have a significant impact on the reliability of the evaluation results and exclude the possibility of conducting a number of types of tests of prosthetic heart valves on it.

Partially, these shortcomings were eliminated in subsequent designs of stands for the study of artificial heart valves made in Russia and abroad (RF patents for PM No. 32387 class A61F 2/24 and No. 34080 class A61F 2/24, US patents for inventions No. 5899937 , 3868536, 3758237, etc.).

As a prototype, an experimental stand for the study of heart valves, published in the journal "Herald of Surgery named after I.I. Grekov" (St. Petersburg, 2004. - Volume 163. - No. 5. - P.25-30) was adopted. The well-known stand contains a control panel, a computer and a monitor with information processing and control signaling systems, a flow meter with sensors, aortic, atrial and ventricular reservoirs with devices for attaching test valves, solenoid valves, ECHO cardiograph, video camera, VCR, amplifier and differential load cell pressure.

Significant disadvantages of the known stand for the study of heart valves are a significant increase in the internal volumes of the blocks through the use of the static method of creating residual pressure and the dependence of performance on the position of the tested heart valves in space.

The technical result of the utility model is to smooth out the pulsations of the circulating solution and to reduce the size of the bench due to the possibility of regulating the residual pressure.

A stand for the study of heart valves is proposed, containing aortic and atrial test chambers with pressure sensors, a pneumatic actuator unit connected by hydraulic lines to the indicated chambers and pneumatic lines through the first electromagnetic pneumatic valve - with the first group of pneumatic devices containing a compressor and a vacuum pump with pressure sensors, a flow meter, a hydraulic damper - a degasser, a control panel with blocks for processing incoming information and issuing control signals, and digital movie cameras.

The difference is that the stand is additionally equipped with a unit for damping and regulating the residual pressure, a second group of pneumatic devices and a second electromagnetic pneumatic valve, and the unit for damping and regulating the residual pressure is connected by hydraulic lines to the aortic test chamber and through the hydraulic damper-degasser to the atrial test chamber, and pneumatic lines are connected through the second electromagnetic pneumatic valve with the second group of pneumatic devices.

A further difference is that the damping and residual pressure control unit contains a housing separated by an elastic membrane, the supmembrane cavity being connected by its pneumatic line to the second electromagnetic pneumatic valve, and the submembrane cavity is equipped with an adjustable diaphragm mounted on the inlet of the hydraulic line connecting it to the aortic test chamber and connected by a hydraulic line to a hydraulic damper-degasser.

The advantages of the proposed stand for the study of heart valves are:

the ability to create a given residual pressure;

smoothing of periodic pulsations of pressure;

reduction of internal volumes and geometric dimensions due to the abandonment of the static method of creating residual pressure;

independence of the operating characteristics of the tested heart valves from their position in space;

ensuring the tightness of all nodes of the stand, which allows the use of various solutions, including poisonous, as a working fluid;

the possibility of temperature control of the elements of the block, etc.

The essence of the utility model is illustrated by drawings, where Fig. 1 shows a block diagram of a stand for examining heart valves, and Fig. 2 shows a block of damping and regulation of residual pressure (in a section).

The stand for the study of heart valves contains aortic 1 and atrial 2 test chambers, which have seats for the installation of two investigated valves. The chambers are filled with a working fluid using a circulatory system consisting of a pneumatic hydraulic actuator 3, a damping and residual pressure control unit 4, and a hydraulic damper-degasser 5 connected to each other and to the test chambers 1 and 2 using hydraulic lines 6. The stand has ultrasonic flow sensors 7 installed at the exit of the aortic test chamber 1 and the entrance of the atrial chamber 2 and transmitting information to the measuring units 8 of the flow meters. The first electromagnetic pneumatic valve 9 is connected by pneumatic lines 10 to the first group of pneumatic devices, including a compressor 11 and a vacuum pump 12. A damping and residual pressure control unit 4 is connected to the output of the aortic test chamber 1, which is connected by a hydraulic line 6 to a hydraulic damper-degasser 5 and a pneumatic pipe 13 through a second electromagnetic pneumatic valve 14 to the second group of pneumatic devices - compressor 15 and vacuum pump 16. Test chambers, pneumatic drive unit, as well as compressors and the vacuum pumps of both groups are equipped with pressure sensors 17. To monitor and record the research process, digital cameras 18 are used. The control unit for processing units

information and the issuance of control signals is represented by a multi-channel analog-to-digital converter 19, a computer 20 and a multi-channel digital-to-analog converter 21. The damping and control unit for the residual pressure comprises a housing 22 with a cover 23, between which an elastic membrane 24. A supmembrane cavity of the housing through the second electromagnetic pneumatic valve is installed 14 is connected by pneumatic lines 13 to the compressor 15 and the vacuum pump 16. The submembrane cavity of the housing is equipped with an adjustable diaphragm 25 installed on the inlet pipe 26 of the hydraulic line 6, connecting the cavity with the aortic test chamber 1. The submembrane cavity is also connected through the side surface of the casing by the hydraulic line 6 to the hydrodamping-degasser 5.

After installing the tested valves in the seats of the atrial 2 and aortic 1 test chambers, the internal volumes of the hydraulic circulatory system are filled with working fluid (pneumatic actuator 3, aortic 1 and atrial 2 test chambers, damping and regulation unit for residual pressure 4, hydraulic damper-degasser 5 and connecting hydraulic lines 6), while in block 4, the adjustable membrane 25 is pre-installed in a predetermined position relative to the elastic diaphragm 24 by moving I have it through pipe 26. Upon completion of the system tightness check using computer 20, the multichannel digital-to-analog converter 21 includes compressors 11 and 15, vacuum pumps 12 and 16. Upon reaching the specified pressure and vacuum levels in the pneumatic lines 10, 13, signals from the sensors 17 enter through an analog digital converter 19 to a computer 20 that implements the test mode program.

The beginning of the test cycle is the supply of a voltage pulse to the electromagnetic pneumatic valve 9 from the computer through a multi-channel digital-to-analog converter 21, which

in the open position connects the output of the compressor 11 to the inlet of the pneumatic actuator 3. The latter supplies the working fluid via hydraulic line 6 to the aortic test chamber 1. Under the action of a hydraulic pulse, the test valve in the atrial chamber 2 closes, and the valve in the aortic test chamber 1 when the pressure exceeds the pressure in unit 4, opens and passes the working fluid through the ultrasonic sensor 7 of the measuring unit of the flow meter 8 into the damping and regulation unit of the residual pressure 4. Under de Due to the pressure difference, the elastic membrane 24 in the block body bends to the upper extreme position, while a part of the liquid occupies a submembrane volume in the body, and the other part through the adjustable diaphragm 25 and hydraulic line 6 enters the hydraulic damper-degasser 5. After a specified time, the computer 20 through the multichannel the digital-to-analog converter 21 supplies an electrical signal to an electromagnetic pneumatic valve 14 and provides another electrical signal to an electromagnetic pneumatic valve 9, while the electromagnetic pneumatic valve 9 connects the vacuum line 10 of the vacuum pump 12 to the inlet of the pneumatic actuator 3, which causes the valve to close in the aortic test chamber, and the electromagnetic pneumatic valve 14 connects the compressor 15 to the pneumatic line 13 of unit 4. Under pressure from the compressor 15, the elastic membrane 24 bends in the block body to the other side and displaces the working fluid from the submembrane space into the reservoir of the hydrodamping-degasser 5. As a result, in the submembrane space of the block 4 body and in the aortic the torture chamber 1 with the test valve closed in it, residual pressure is created and maintained due to air pressure in the pneumatic line 13 of the compressor 15 and the position in the housing of the adjustable diaphragm 25. Due to the vacuum in the pneumatic actuator 3 and the difference in hydraulic pressures, the valve in the aortic test chamber 1 continues to remain closed, and the working fluid begins to flow from

hydrodamping-degasser 5, while opening the test valve in the atrial chamber 2 and filling the pneumatic actuator 3, which prepares the hydraulic system for the next cycle. Throughout the entire cycle, with the help of pressure sensors 17 and a flow meter 7, 18, continuous recording and storage in the computer 20 of the fluid flow parameters and the operating characteristics of the tested valves is provided.

The input and design of the damping and residual pressure control unit maintains the specified pressure in the aortic test chamber in the inter-pulse phase of the pulsating fluid flow time and reduces the height of the stand.

Claims (2)

1. The stand for the study of heart valves, containing aortic and atrial test chambers with pressure sensors, a pneumatic actuator unit connected by hydraulic lines to the indicated chambers and pneumatic lines through the first electromagnetic pneumatic valve - with the first group of pneumatic devices containing a compressor and a vacuum pump with pressure sensors, a flow meter, a hydraulic damper a degasser, a control panel with blocks for processing incoming information and issuing control signals, and digital movie cameras, characterized in that additionally equipped with a unit for damping and regulating the residual pressure, a second group of pneumatic devices and a second electromagnetic pneumatic valve, the unit for damping and regulating the residual pressure is connected by hydraulic lines to the aortic test chamber and through the hydraulic damper-degasser to the atrial test chamber, and the pneumatic pipes are connected through the second electromagnetic valve a group of pneumatic devices. 2. The stand according to claim 1, characterized in that the damping and residual pressure control unit comprises a housing separated by an elastic membrane, the supmembrane cavity being connected by its pneumatic line to the second electromagnetic pneumatic valve, and the submembrane cavity is equipped with an adjustable diaphragm mounted on the inlet pipe of the hydraulic line connecting it with an aortic test chamber, and is connected by a hydraulic highway to a hydrodamping-degasser.