RU2311893C1 - Device for testing artificial heart valve in blood circulation phantom - Google Patents

Abstract

FIELD: medical engineering.

SUBSTANCE: device has two-sectioned chamber having inlet and outlet section manufactured from transparent material. The chamber has internal canal repeating heart cavity or aorta shape and place for implanting the valve. Openings are available in chamber section walls having metal wires and nipples fixed and sealed in them. The outlet chamber section has optical window in its end and tap holding mounted electrode. Cavity is available at the place the sections are connected to each other for fixing and sealing the valve allowing its rotation. The device has pulse generator, time shift source, system for control blood circulation phantom, frequency meter unit, illumination system, pressure and flow sensors. Generator inlet is connected to the system for control blood circulation phantom via the time shift source, the first generator outlet is connected to metal wires and electrode and the second one to the frequency meter unit. The illumination system is mounted on the chamber. Pressure sensor is connected to chamber sections by means of plastic mains via the nipples. The flow sensor is mounted in outlet section tap.

EFFECT: enhanced effectiveness in visualizing model liquid flow in heart valve and determining large shift stress zones.

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Description

The invention relates to medical equipment and can be used to assess the quality of an artificial heart valve from the point of view of trauma to blood cells and the formation of blood clots.

A known method for determining the hemodynamic characteristics of an artificial heart valve. A device for implementing the method includes an artificial heart valve, a hydrochannel, an artificial ventricle with a pneumatic drive, a collecting tank and a pump, in addition, the device contains strain gauges, a synchronization and control unit, movie cameras and lasers. [A.S. SU No. 1422423]

The disadvantages of this method is the high cost of the applied device and reagents, insufficient measurement accuracy.

A device for installing the aortic valve or frameless bioprosthesis of the aortic valve when conducting studies in a pulsating flow. The device comprises nozzles for connecting valve portions with a hydrodynamic circuit, a chamber of elastic material for accommodating an aortic valve or aortic valve bioprosthesis in it, and a damping device on which one of the nozzles is mounted for movement. [RF patent No. 2237452]

The disadvantage of this device is the inability to visualize the fluid flow in the heart valve, which does not allow to identify areas of large shear stresses and stagnation zones in the heart valve and to obtain an accurate assessment of the hydrodynamic characteristics of the artificial heart valve, and therefore to evaluate the quality of its work.

Known phantom for the study of artificial heart valves and ultrasound, selected for the prototype. The phantom contains a multisectional chamber made of transparent material with an internal channel imitating the shape of the cavity of the heart or aorta, and a place for installing the valve; holes are made in the chamber wall. A number of sections are equipped with optical windows at the end and bends. The inlet section is for installing a mitral artificial heart valve, and the outlet is for the aortic. Ultrasonic sensors are installed in the output section to measure the velocity of the model fluid. The sensors move along cylindrical guides passing through the openings of the outlet section. [US Patent No. 5052934]

The disadvantage of this device is the inability to visualize the fluid flow in the heart valve, which does not allow to identify areas of large shear stresses and stagnation zones in the heart valve and to obtain an accurate assessment of the hydrodynamic characteristics of the artificial heart valve, and therefore to evaluate the quality of its work.

The objective of the invention is the visualization of fluid flow in the heart valve, the determination of areas of large shear stresses and stagnation zones in the artificial heart valve, assessing the quality of the artificial heart valve from the point of view of trauma to blood cells and the formation of blood clots.

To solve the problem, a device for testing an artificial heart valve in the phantom of blood flow is proposed. The device is a two-section camera consisting of inlet and outlet sections made of a transparent material, for example plexiglass sanded to transparency. The walls of the chamber are made flat. The camera has an internal channel that mimics the shape of the cavity of the heart or aorta, and a place for installing the valve. Holes are made in the walls of the chamber sections in which metal wires and fittings are hermetically fixed. The output section of the camera is equipped with an optical window at the end and a tap in which the electrode is mounted. A recess has been made at the junction of the sections for hermetically securing the valve with the possibility of its rotation. In addition, the device further comprises a pulse generator, a source of temporary shifts, a control system for the phantom of blood flow, a frequency meter, a lighting system, pressure and flow sensors. The input of the generator through a source of time shifts is connected to the blood flow phantom control system, the first output of the generator is connected to metal wires and an electrode, and the second to a frequency meter. The lighting system is mounted on the camera. The pressure sensor is connected by plastic lines through the fittings to the sections of the chamber, and the flow sensor is installed on the outlet of the outlet section.

The lighting system includes, for example, a cylindrical lens, a slit diaphragm, lighting and cooling devices.

As a lighting device, for example, a pulsed light source, a halogen lamp, an LED, a laser can be used.

As the electrode, for example, a metal plate or a metal ring can be used.

Metal wires can be made, for example, of tungsten, platinum, etc.

The installation of a special camera — a camera for visualizing the flow of the solution flow in the valve, made, for example, of plexiglass ground to transparency and having a certain external shape minimizes optical distortions caused by the refraction of light at the interface between plexiglass and air. The internal shape of the chamber simulates the Valsalva sinuses, either the atrium or the ventricle of the heart, which affects the size and location of stagnant zones and areas of large shear stresses, the accuracy of the obtained characteristics of the velocity field in the valve. The camera is made of two sections for the possibility of tight installation of the valve and its rotation relative to the axis of the channel. The possibility of rotation allows the valve to be installed at different angles to the metal wires and electrode, which makes it possible to determine the location of stagnant zones and areas of large shear stresses in various longitudinal sections of the chamber sections. Metal wires are cathodes, and the electrode is an anode, to which a pulse voltage is applied. Moreover, in the case of using electrolyte as a model fluid, an electrolysis reaction occurs with the release of hydrogen at the cathode. When a short impulse is applied, small hydrogen bubbles break off the wire in the form of a time line moving along with the flow of the model fluid, thus visualizing the velocity profile in the cross section, which makes it possible to assess the quality of the artificial heart valve from the point of view of trauma to blood cells and the formation of blood clots.

Thus, only a set of distinctive features allows us to solve the problem.

Figure 1 shows a device for testing an artificial heart valve in the phantom of blood flow.

The device contains an artificial heart valve 1, fixed in the recess 2 of the inlet section 3 in the place of its connection with the outlet section 4. The sections have openings 5, where metal wires 6 are hermetically fixed, and openings 7 with fittings 8 inserted into them, which are through plastic lines 9 are connected to a pressure sensor 10. The output section has an optical window 11 at the end and an outlet 12 in which the electrode 13 is fixed. A flow sensor 14 is installed at the outlet. The wires and electrode are connected to the output of the generator 15, the input of which is through the source of temporary shifts 16 is connected to the control system of the phantom of blood flow 17. The second output of the generator 15 is connected to the frequency meter 18. Outside, a lighting system is fixed on the camera, which consists of a light source 19, a lens 20, a diaphragm 21. During operation of the system, a cooling device 22 can be used to cool the camera. When testing an artificial heart valve, video cameras 23 and 24 can be used to visualize the movement of the valve flaps and hydrogen bubbles.

The test of the artificial heart valve in the device is implemented as follows.

The valve 1 is fixed in the recess 2 between the input 3 and output 4 sections. The operation of the valve is controlled by a video camera 23. Into the holes 5 hermetically fasten, for example, tungsten wires 6 with a diameter of 10-30 microns. The device is hermetically connected to the hydrodynamic circuit of the phantom of blood flow, which is filled with a weak solution of an electrolyte, for example, sodium sulfate. Using the control system 17 set the mode of operation of the phantom of blood flow, i.e. set the frequency and amplitude of the flow and get a pulsating flow of the solution in the device. The operation of the phantom of the blood flow is controlled by the readings of the pressure sensor 10 and the flow sensor 14. Using a source of time shifts 16, a time shift of 0.01-0.50 s is set between the pulses of the system 17 and the pulses of the generator 15. This makes it possible to generate time lines of hydrogen bubbles 25 v various phases of the artificial heart valve 1, for example, in the phase of opening its locking element. The oscillator 15 sets the amplitude of the pulses 50-150 V, their duration is 1-5 ms and the generation frequency is 2-50 Hz of the time lines of the hydrogen bubbles 15, controlling the latter by the frequency counter 18. The light source 19 is turned on and the generator 15 is started, and the mode is selected in the latter pulse generation, for example, continuous or single - in the form of a burst of pulses. Observe or record using a camera or video camera 24 time lines of hydrogen bubbles 25 in the heart valve.

Example. A double-leaf artificial heart valve Meding was fixed in a device for testing an artificial heart valve, which was installed in the phantom of blood flow. A physiological solution was poured into the phantom, in which sodium sulfate of the required concentration was dissolved. Tungsten wires were installed according to the described procedure. Using the phantom control system, the contraction frequency was set to 70 beats / min, systole duration 0.3 s, minute flow rate 5 l / min. At the same time, halogen spotlights were used as a light source, the sections were cooled by a centrifugal fan. The movement of hydrogen bubbles was recorded using a Sony video camera. The flow was visualized in four planes parallel to the axis of the channel, and in three sections behind the valve. After turning the valve through 90 °, visualization was repeated in the same sections.

The image of the time lines of the hydrogen bubbles (Fig. 2a) is transferred to a computer via an input board, digitized, and instantaneous and averaged over several cycles of the pulsating flow of the distribution of the solution velocity in the artificial heart valve (Fig. 2b) are used according to well-known formulas (Lu LJ, Smith CR Image processing of hydrogen bubble flow visualization for determination of turbulence statistics and bursting characteristics // Experiments in Fluids, 1985, No. 3, p. 59-74). Large shear stresses cause deformation or destruction of blood cells, and stagnant zones create conditions for thrombus formation.

The obtained velocity distributions determine areas of large shear stresses and stagnation zones in the artificial heart valve (Fig.2c), where 25 is the valve seat; 26 - valve flap; 27 - jet high-speed flow; 28 - region of vortex formation with large shear stresses; 29 - stagnant low-speed zone with low shear stresses.

Based on the obtained structure of the fluid flow in the valve (Fig.2c), recommendations are formulated on changing the design of the artificial heart valve, for example, the shape and opening angle of its locking elements to reduce the degree of hemolysis of blood and thrombosis on the valve, and therefore, improve the quality of life of patients with implanted artificial heart valve.

Claims (1)

A device for testing an artificial heart valve in the phantom of blood flow, which is a multisectional chamber made of transparent material with an internal channel that mimics the shape of the cavity of the heart or aorta and a place for installing the valve, holes are made in the chamber walls, and its outlet section is equipped with an optical window end and outlet, characterized in that the chamber consists of two sections, a recess is made at the junction of the sections for hermetically securing the valve with the possibility of its rotation, in the walls of the chamber Additional holes have been made in which metal wires — cathodes and fittings — are hermetically fixed, and an electrode — anode is installed in the outlet section of the output section; in addition, the device additionally contains a pulse generator, a source of temporary shifts, a phantom control system, a frequency meter, an illumination system, pressure sensors, and flow, and the generator input through a source of temporary shifts is connected to the phantom control system, its first output is connected to the wires and electrode, and the second to the frequency counter, lighting system akreplena on the camera, the pressure sensor is connected through fittings from the camera, and a flow sensor is installed at the tap.

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