RU2345739C1 - Device for destruction of biological tissues - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: device contains body and cannula-irrigator (CI). In body through cylindrical cavity is made. From one side to body hermetically attached is CI, whose hole is connected with cylindrical cavity of body. On the opposite side of body, in cylindrical cavity, cylindrical piston is hermetically placed, forming compression chamber between anterior piston surface and place of CI fixation. From side of posterior piston surface impact device with striker is placed. Piston and striker are placed coaxially with body cylindrical cavity and each other with possibility of their axial travel. System of liquid supply to compression chamber is attached to body through reach-through hole in it by means of valve with gate. From compression chamber side, rod rests against gate. Gate centre is superposed with rod centre, rod axis is perpendicular to gate plane; rod is placed with possibility of axial travel.

EFFECT: increase of device operation efficiency, ensuring patient and operator safety, convenience of operator work.

Description

The invention relates to medicine, namely to ophthalmology, and can find application in general surgery, neurosurgery, oncology, if necessary, local tissue separation.

The closest analogue is a device for the destruction of biological tissues, described in A.S. 753434.

The device comprises a housing, a working tip, irrigation and suction cannulas located along the housing towards each other.

The device has the following disadvantages:

The destructible (destructible) area, for example, cataracts, is not affected by a direct liquid flow, but only by a lateral one with possible ejector suction of the destructible masses into the zone of a direct liquid stream flow.

This circumstance reduces the effectiveness of destruction.

The spatially separated system of creating a high pressure liquid and the active element of the irrigator with a cannula create undoubted inconvenience for the operator.

In addition, the supply of fluid to the cannula of the irrigator at a pressure of 30 atmospheres requires compliance with the safety rules of the patient and the operator.

The technical result is to increase the efficiency of the device, compliance with safety rules for the patient and the operator, as well as the convenience of the operator

The technical result is achieved by the fact that in the device for the destruction of biological tissues, comprising a housing and an irrigator cannula, according to the invention, a through cylindrical cavity is made in the housing, an irrigator cannula is tightly connected to the housing on one side, the opening of which is connected to the cavity from the opposite side a cylindrical piston is hermetically placed on the side of the body in the cavity with the formation of a compression chamber between the front surface of the piston and the attachment point of the irrigator cannula, and from the back surface a piston coaxially with the piston has a striking device with a striker, while the piston and striker are arranged sequentially and coaxially to the cylindrical cavity of the body with the possibility of axial movement, the system for supplying liquid to the compression chamber through a valve with a shutter and an elastic sealing ring is connected to the body through an opening in it, the rod abuts the valve from the side of the compression chamber, while the center of the valve is aligned with the center of the rod, the axis of the rod is perpendicular to the plane of the valve, and the rod is installed in the housing with the possibility of axial movement about (reciprocating) movement.

The outlet of the irrigator cannula is formed in the form of a nozzle.

The technical result of the device is also achieved by the fact that the nozzle outlet in the irrigator cannula can be of any shape, for example, cylindrical, axisymmetric, rectangular or elliptical.

The device is illustrated in the drawing, which shows a General view of the device.

The destruction device comprises a housing 1, a through cylindrical cavity is made in the housing 1. On one side, a cannula-irrigator (KI) 2 with a nozzle 3 is hermetically connected to the housing 1, a hole in the KI 2 is connected to the cylindrical cavity of the housing 1. On the opposite side of the housing 1, a cylindrical piston 4 is sealed in its cavity. Between the front surface of the piston 4 and the attachment point KI 2 in the cylindrical cavity of the housing 1 is formed by a compression chamber 5, and on the side of the rear surface of the piston 4 in the cavity of the housing 1 is placed the drummer 6 of the percussion device 7. The piston 4 and the drummer 6 are arranged sequentially and coaxially to the cylindrical stripes ty of case 1 and to each other. A fluid supply system 8 to the compression chamber 5 is connected to the housing 1 through a through hole in it. Between the compression chamber 5 and the fluid supply system 8, a valve with a disk shutter 9 and a sealing ring 10 is placed, while the center of the shutter 9 is installed on the side of the compression chamber 5 rod 11, the axis of which is perpendicular to the plane of the valve. To return the piston 4 to its original position, there is a spring 12. The piston 4 has a seal 13.

The device operates as follows:

In the compression chamber 5 through the fluid supply system 8, liquid, for example water, is supplied. When the impact device 7 is activated, its impactor 6 comes into contact with the rear surface of the piston 4. At the same time, during the contact, the impactor 6 and the piston 4 exchange moments of momentum. The piston 4, based on the mass ratio of the hammer 6 and the piston 4 and the speed of the hammer 6 at the moment of touching the piston 4, receives a certain momentum of force. In the compression chamber 5 and KI 2 with the nozzle 3 filled with liquid, due to the displacement of the piston 4 during impact, a pressure arises, the value of which can reach 1000 kgf / cm ² = 1000 atmospheres at the moment of impact, which affects the destructible area. Then the pressure on the tissue decreases, as the magnitude of the force impulse decreases. To ensure the return of the piston 4 to its original position, a return spring 12 is provided in the device

With increasing pressure in the compression chamber 5, a reverse discharge of liquid into the fluid supply system 8 is possible, since the pressure in it does not exceed 1 kgf / cm ² . To prevent backflow of liquid, the valve 9 located in the compression chamber 5 is provided with a sealing elastic ring 10. Between the disk valve 9 and the ring 10 there is a small gap during the filling of the compression chamber 5 and KI 2 with the nozzle 3. At the moment of impact, with increasing pressure in the compression chamber 5, the shutter 9 is shifted towards the sealing ring 10 and shuts off the fluid supply to the compression chamber 5. In the case when the pressure in the compression chamber 5 must be reduced, for example, to wash the capsule bag for installation of art after the cataract removal, or in other cases, the initial clearance between the valve 9 and the ring 10 can be changed. An increase in the initial gap between them leads to an increase in the response time of the valve and, accordingly, to a decrease in the effective pressure when the liquid is ejected from the nozzle 3. A decrease in the gap leads to the opposite effect. Changing the specified gap provide a cylindrical rod 11, the axis of which coincides with the center of the valve 9 and is perpendicular to its plane. The rod 11 through a hydraulic seal (not shown) is brought to the outer surface of the housing 1 and is equipped with a device for adjusting the gap between the valve 9 and the sealing ring 10 (not shown) and, therefore, the pressure in the compression chamber 5 at the time of impact.

It should be noted that the percussion device 7 can be electrodynamic, mechanical, thermal, or magnetic, provided that the percussion device provides shock formation along the piston, providing displacement of the piston 4 with the creation of the pressure necessary for the destruction of the compression chamber 5

Before the introduction of KI 2 with a nozzle 3 into the area of the lens or vitreous body, or any other tissue that needs to be destroyed, under local anesthesia, in the cornea, two paracentesis are performed paralymbally at 2 and 9 hours, the eyes are introduced into the anterior chamber solution of mesatone and viscoelatics

Through one of the paracentesis using an irrigation cystotome or tweezers for capsulorexis, the front lens capsule is opened in a circle, i.e. perform continuous circular capsulorexis, and hydraulic separation of the lens substance from the anterior and posterior lens capsules, and separation of the lens nucleus from the lens mass using a fluid stream from the syringe.

Then, through the paracentesis, the lens nucleus is rotated using an independent irrigation cannula or a special hook to finally break the bonds between the nucleus and the lens capsule bag. Then, the anterior chamber of the eye is again filled with viscoelastic, through one of the paracentesis, the working tip of the KI 2 device with nozzle 3 is inserted into the anterior chamber, and through the second paracentesis, a standard irrigation and aspiration tip is made, and the lens core is hydromonitorously destroyed with appropriate aspiration of its fragments using standard irrigation and aspiration tip. In this case, a pulsed liquid jet is used at the leading edge of up to 1000 kgf / cm ² at a distance from the nozzle to the destructible fabric from 0 to 0.5 mm.

To wash the capsule bag of the lens from proteins and cellular structures, they reduce the pressure in the stream and wash it.

Claims (1)

A device for the destruction of biological tissues of the eye, comprising a body and a cannula-irrigator (CI), characterized in that a through cylindrical cavity is made in the casing, a CI is hermetically connected to the casing on one side, the opening of which is connected to the cylindrical cavity of the casing, on the opposite side of the casing a cylindrical piston is hermetically placed in the cylindrical cavity with the formation of a compression chamber between the front surface of the piston and the attachment point of the CI, and the shock a trinity with a striker, the piston and the striker being located coaxially with the cylindrical cavity of the body and with each other with the possibility of axial movement, to the body through a through hole there is connected a system for supplying liquid to the compression chamber through a valve with a shutter, while to the shutter from the side the compression chamber abuts the stem, the center of the shutter is aligned with the center of the stem, the axis of the stem is perpendicular to the plane of the shutter, and the stem is mounted for axial movement.