RU2299044C2 - Method for arranging carcass-free biological cardiac valve in testing stand and apparatus for performing the same - Google Patents

Abstract

FIELD: medicine, namely cardio-vascular surgery, possibly investigations concerning parameters of valves of aorta and lung artery and their carcass-free substitutes.

SUBSTANCE: method comprises steps of placing valve in vertical position in chamber between outlet of pumping device of testing stand and damper. Valve is secured by means of pneumatic suctions arranged in commissural zones of valve and fixed along their height. Apparatus includes testing chamber for valve, pumping device and damper. Housing of apparatus is provided with struts having pneumatic suctions arranged in commissural zones of valve. Struts have shape corresponding to that of commissural zones of valve; their walls engaging with valve are elastic ones and pneumatic suctions are arranged in them. All other walls are rigid ones. Space between walls of struts is communicated with pneumatic suctions and with pneumatic sucking off device.

EFFECT: possibility for keeping natural contours of valve.

4 cl, 2 dwg

Description

The invention relates to medicine, namely to cardiovascular surgery, and can be used in studies in a pulsating fluid flow to study the characteristics of biomechanics, hydrodynamics of native valves of the aorta and pulmonary artery and their frameless substitutes.

Frameless biological valves do not contain a support rigid or flexible frame in their design and form their shape by connecting the sewn parts of the commissural rods of the aortic valve.

The fastening of frameless biological valves in the test chambers of the stands is the most vulnerable point in the design of pumping devices both in terms of the reliability of fastening and the adequacy of the tested loads.

A device for mounting frameless valves containing nozzles (connectors) of a cylindrical shape or in the form of a truncated cone, with a seat and a supply part, a corrugated pipe with a valve under investigation and fasteners (V.I. Shumakov and others. Artificial heart. - Leningrad: Science, 1988 .-- S.60-61). The supply section of the valve is rigidly connected to the corrugated pipe and mounted on the supply side of the nozzle.

One of the main disadvantages of the known device is the rigid mounting of the valve on the nozzle, which does not allow it to change its size vertically. In addition, the outlet section of the valve is connected to the pipe semi-rigidly (4-6 ligatures), and the lack of tightness leads to the fact that during the reverse backpressure pulse, the load on the valve occurs both inside it and on the outer walls of the sinuses, which leads to its unnatural deformation. Due to the location of the valve in the water volume and its communication with the damper, small vibration occurs with an increase in the frequency of drive cycles over 140 cycles per minute, which sharply worsens the hydrodynamic characteristics of the valve under test, that is, they significantly differ from the hemodynamic parameters in the natural heart of a person.

A known method and device for mounting a frameless valve, which is based on the turnstile principle of fixing the sewing cuff to the connector of the artificial ventricle of the stand, and the outlet section of the valve is turnstile attached to the U-shaped tee of the movie camera located on the sliding sleeve, and the connector of the artificial aorta (RF patent No. 2237452 , CL A61F 2/24, published in 2004). The known method of attachment and a device for its implementation allow you to change the length of the frameless biological valve in the vertical plane during the pulse wave, provided that the valve body with the Valsalva sinuses and sutured mouths of the coronary arteries are saved. Important disadvantages of the known technical solutions are the impossibility of mounting a frameless valve with cut out Valsalva sines and the high probability of injury to the valve in the supply and output sections of the elements of the turnstile nodes, which leads to compression and rupture of the biological tissue of the valve.

A device for attaching a frameless biological valve is provided, comprising an elastic pipe (chamber), a removable rigid nozzle with a supply part on which through channels are located, and elastic nozzles fixed to end cuffs in the supply and output sections of the valve and connected by fasteners to the supply part nozzles and damper fitting (certificate for utility model No. 23567, class A61M 1/10, priority dated November 28, 2001). The essence of the method used in this design is that the valve hangs on a vertical pipe, and the lower part of the pericardial pipe is in an unstretched state, which provides relatively free radial movement and does not limit the change in the shape of the sewn cuff. This mounting method provides a relatively adequate movement of the components of the supply section of the valve, but does not allow free movement in a vertical plane. The device does not exclude the possibility of a spiral motion of the valve under investigation around its axis at large amplitudes of the hydraulic pulse.

A method for “soft” mounting a frameless biological heart valve on a test bench is proposed, including installing it in a vertical position between the output of the pumping device of the test bench and a damper.

The difference of the proposed method lies in the fact that the valve is mounted using pneumatic suction cups located in the commissural zones of the valve at a fixed height.

A device for implementing the indicated mounting method comprises a chamber in which a valve is installed, installed between the outlet of the pumping device of the test bench and the damper, hermetically connected to it.

The difference between the device for attaching a frameless biological heart valve is that it contains a housing equipped with racks with pneumatic suction cups, the housing mounted at the base of the chamber, and the racks are made in the form of commissural zones, while the walls of the housing and racks in contact with the valve are made elastic and air suction cups are placed in them, and the remaining walls are made rigid, and the space between the walls of each rack is communicated with a pneumatic suction pump.

Air suction cups can be made with a hole diameter of 0.1-2.0 mm based on 5 to 50 holes per 1 cm ² surface.

The difference between the device is also that the camera is rigid and equipped with a removable cover with a sealing ring and a connector for connecting to the damper, with fittings for connecting the suction cups to the suction pump mounted on its side surface.

The main advantage of the claimed method of mounting a frameless valve is its non-invasiveness, while the natural forms of the spaces inside the valve are preserved and it retains its natural function without creating disturbances to the fluid flow, including during the passage of a pressure pulse.

In addition to these advantages, common to both the method and the device, the design of the fastener assembly allows sterilizing racks with suction cups and fastening parts in contact with the test valve and the working solution, and use it for different valve sizes.

The invention is illustrated in the drawing, where figure 1 shows a General view of a device for implementing the proposed method, and figure 2 - body with a stand in section.

The device comprises a rigid chamber 1, for example, of a cylindrical shape, which is tightly attached to the outlet of the pumping device 2 of the test bench and to the inlet of the damper 3 using a threaded or other connection. Inside the chamber, a test frameless biological valve (not shown) is installed, for which the camera has a removable cover 4 with connector 5. For mounting the valve between the base 6 of the chamber and the output of the pumping device 2, a housing 7 with racks 8 is installed, which is located around the valve in its commissural zones, when Volume racks, especially their contact with the valve surface, must match the shape of these zones. The casing is fastened using a union nut 9, and the tightness of the connection is ensured by the installation of o-rings 10 and 11. The sides of the casing and racks in contact with the commissural zones of the valve are made elastic and air suction cups 12 are installed for mounting the valve. The remaining sides of the hull and racks are made rigid. To limit the deflection of the elastic wall under the influence of rarefaction, a rigid restrictive support in the form of a mesh 13 is installed inside the housing and racks under the pneumatic suction cups 12. The cavity between the walls of the housing and racks through the fittings 14 is connected by flexible hoses 15 to the fittings 16 in the chamber housing and then through the valve 17 - pneumatic suction pump 18.

To ensure the tightness of the connection of the removable cover 4 with the camera 1 has a sealing ring 19.

The shape and parameters of the suction cups are selected taking into account the whole complex of factors - the design of the biological valve, the features of the elastic material used, the suction cups, the parameters of the pneumatic suction pump, the test program, etc.

Taking into account that under the conditions of safety and reliability of fastening, the vacuum created by the pneumatic suction pump should be within 20-60 mm Hg, the dimensions of the holes of the pneumatic suction cups should be in the range 0.1-2.0 mm, with their number from 5 to 50 pcs. on 1 cm ² surface. With a decrease in the diameter of the holes and the number of suction cups, the reliability of the fastening of the valve decreases, and with an increase in these parameters beyond the specified limits, injury to the valve tissue is possible.

The following is a description of the operation of the device for mounting a frameless biological heart valve on a test bench.

To install the frameless valve from the test chamber 1, remove the cover 4 and the chamber together with the housing 7 are hermetically connected using a union nut 9 to the output of the pumping device 2 of the test bench. One of the struts 8 is applied to one of the commissural zones of the test valve, the corresponding valve 17 is opened, and the suction cups 12 are sucked to this valve zone, after which this procedure is carried out for the next two racks and commissural zones of the valve. The process of assembling the device ends with the installation of the sealing ring 19, the cover 4 and the connection of the connector 5 with the damper 3. When testing the frameless valve, the pressure pulse flows through the outlet section of the pumping device 2 into the subvalve space and exerts pressure on the valve elements. A body with racks supports the valve and holds it in a vertical plane, a pressure hydraulic pulse and a volume of fluid flow around the valve’s internal structures and exit into the pneumatic damper, where the pulse wave is partially smoothed out. The volume of fluid passing through the valve flows into the circulation system, and the components of the damper create a backward decaying pressure wave on the valve’s internal structures with the formation of physiological flows and vortices, and the valve flap closes. In this case, the biological tissue of the valve is not damaged, and the movement of the jets of liquid is formed by the natural biological elements of the internal spaces of the valve and does not affect the physiological function of the valve as an element of the circulating system. When pressure equalizes inside the cavity of the struts with atmospheric pressure, the fixed valve elements are released. Using sterile fixing components of the mounting unit and the chamber as a whole, made of metal, glass, Teflon, etc., and a sterile working solution, various studies can be carried out while maintaining the sterility of the valve under test. If the biological frameless valve does not contain Valsalva sines, then artificial sines and a transitional upper pipe are attached to the posts. The mounting principle remains the same as for frameless valves with preserved Valsalva sines.

Additional advantages of the proposed method and device are quick and gentle valve fixation, as well as the ability to quickly change samples of test valves of various sizes.

Claims (4)

1. The method of mounting a frameless biological heart valve on a test bench, including installing it in a vertical position in the chamber between the output of the pumping device of the test bench and a damper, characterized in that the valve is mounted using pneumatic suction cups located in the commissural zones of the valve with a fixed height. 2. A device for mounting a frameless biological heart valve on a test bench, comprising a valve chamber installed between the output of the pumping device of the test bench and a damper, hermetically connected to them, characterized in that it contains a housing provided with struts with pneumatic suction cups, the housing being fixed in the base of the chamber, and the racks are made in the form of commissural zones, while the walls of the housing and racks in contact with the valve are made elastic and the air suction cups are placed in them, and The walls are made rigid, and the space between the walls is communicated with air suction cups and air suction pump. 3. The device according to claim 2, characterized in that the suction cups are made with a hole diameter of 0.1-2.0 mm from 5 to 50 pcs. on 1 cm ² surface. 4. The device according to any one of paragraphs.2 and 3, characterized in that the camera is rigid and provided with a removable cover with an o-ring and a connector for connecting to a damper, with fittings for connecting the suction cups to the suction pump located on its side surface.

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