RU199594U1 - Device for temporary occlusion of great vessels and aorta - Google Patents

Abstract

The device for temporary occlusion of the great vessels and the aorta refers to medical technology, namely to medical and surgical instruments, in particular to a device for temporary occlusion of the great vessels and the aorta. both in hospital and in the field. This is achieved by the fact that the distal end of the inflatable balloon is fixed at the end of the super-rigid guidewire, the guidewire can be reciprocated relative to the catheter, and a sealing gasket is installed in the connector.

Description

The proposed utility model relates to medical technology, namely to medical and surgical instruments, in particular to a device for temporary occlusion of the great vessels and the aorta.

A device for temporary occlusion of the great vessels and the aorta is known, including a catheter, at the distal end of which an inflatable balloon, a J-type guide is installed, and a connector installed at the proximal end of the catheter and a fluid balloon inflation mechanism connected to it, for example, a syringe (see WO2014134215 by class A61M 25/10, 2015).

The known device can be used in the field.

However, it has several disadvantages, namely:

- the complexity of the design associated with the presence of an additional centering element and the use of a double-lumen catheter (one lumen for inserting the guidewire, and the second lumen for balloon inflation);

- the possibility of displacement of the balloon in the event of blood pulses due to insufficient rigidity of the catheter;

- the difficulty of positioning the balloon inside the vessel;

- the lack of reliable fixation of the catheter on the skin leads to the displacement of the balloon in the vessel.

The closest in technical essence to the proposed technical solution is a device for temporary occlusion of the great vessels and the aorta, including a single-lumen catheter, a J-type guide, consisting of a super-rigid part and a flexible part with a J-end, and the flexible part is located outside the distal end of the balloon , and in the lumen of the catheter is placed and hermetically fixed at one end of the super-rigid part of the guidewire at the distal end of which an inflatable balloon is installed, a connector is placed on the proximal end of the catheter and a mechanism for ballooning the balloon with liquid connected to it (see Patent PM No. 172757, class A61M 25 / 10_, 2016)

The technical result solved by the proposed utility model is the creation of a device for temporary occlusion of the great vessels and the aorta, which reduces the trauma of introducing a balloon catheter into the great vessels during its installation, both in a hospital setting and in the field.

The technical result in the proposed utility model is achieved by creating a device for temporary occlusion of the great vessels and the aorta, including a single-lumen catheter, at the distal end of which an inflatable balloon is installed; a J-type guide wire, consisting of a super-rigid part and a flexible part with a J-end, the flexible part being located outside the distal end of the balloon, and the super-rigid part of the guide being sealed in the lumen of the catheter; and located at the proximal end of the catheter, a connector and a fluid balloon inflation mechanism connected thereto; in which, according to the invention, the distal end of the inflatable balloon is fixed at the end of the super-rigid part of the guidewire, the guidewire being able to reciprocate relative to the catheter with a connector, and a sealing gasket is installed in the connector.

The installation of a sealing gasket in the connector ensures complete closure of the catheter from the penetration of liquid into it for balloon inflation.

The advantage of the proposed design is a significant reduction in the diameter of the inflated balloon when it is introduced into the vessels through the introducer, which means that the invasiveness of the balloon catheter installation is reduced.

The essence of the proposed utility model is illustrated by the description below and drawings, where

FIG. 1 shows a general view of the device for temporary occlusion of the great vessels and the aorta before installation in them.

FIG. 2 shows a general view of the device for temporary occlusion of the great vessels and the aorta at the time of its introduction through the introducer and reduction of the balloon diameter.

FIG. 3 shows a view of the device inside a vessel with an inflated occluding balloon.

A device for temporary occlusion of the great vessels and aorta, includes a single-lumen catheter 1 at the distal end, of which an inflatable balloon 2, a J-type guide is installed, and a connector 3 with a sealing gasket 4 installed at the proximal end of the catheter and a mechanism for inflating the balloon with liquid 5 connected to it, a movable limiter 6 of the depth of insertion of the catheter into the vessel and the fixture of the device to the skin 7, located on the proximal part of the catheter. The latch 7 is located proximal to the depth stop 6. In the lumen (not shown in the drawing) the super-rigid part 8 of the guidewire is placed and hermetically fixed at both ends, and the flexible part 9 is located outside the distal end of the inflated balloon 2.

The distal end of the inflatable balloon 2 is fixed at the end of the super-rigid part of the guidewire 8, and the guidewire is capable of reciprocating movement relative to the catheter 1 with connector 3.

The mechanism for inflating the balloon 5 with liquid, depending on technical capabilities, can be made either in the form of a syringe or any mechanism for supplying liquid to the balloon.

The operation of the device for temporary occlusion of the great vessels and the aorta is as follows:

Before the introduction of the catheter 1 with an inflatable balloon 2 into the aorta or the great vessel, the optimal insertion depth is determined by applying the catheter 1 to the patient's body surface.

The point corresponding to the entry point of the catheter 1 with the inflatable balloon 2 into the aorta is fixed using a movable limiter 6 of the depth of insertion of the catheter into the vessel.

Using the straightener 9 of the flexible part 8 with the J-end, the catheter 1 with the balloon 2 is introduced into a pre-installed introducer (not shown in the drawing).

Then the straightener 9 is removed, and the catheter 1 with the balloon 2 is inserted into the aorta or the great vessel under fluoroscopic control.

In the absence of fluoroscopy to inflate the balloon 2, for example, in zone 1 of the aorta, one should focus on the patient's xiphoid process, and for zone II - on the navel.

After the introduction of the inflatable balloon 2 to the indicated mark, the device fixer to the skin 7 is fixed on the patient, which prevents possible displacement of the first. The correct positioning of the balloon is checked by X-ray control.

After confirming the correct position of the balloon, a mixture of contrast agent and saline solution is injected into the catheter in a 1: 1 ratio, diluted in the balloon inflation mechanism with a liquid, for example, a 20 ml syringe, under fluoroscopy or followed by radiography.

The volume of injected fluid is determined from the attached nomogram. An X-ray sign of complete occlusion of the vessel is an elongated (close to rectangular) shape of the balloon 2 along the length of the vessel, which is formed due to moderate over-inflation of the balloon and its spreading along the vascular wall.

In the absence of an X-ray unit, they are guided by the feeling of slight resistance that occurs when a sufficient amount of solution is injected, and the recoil of the piston in the syringe, after which the administration is stopped.

The balloon 2 is inflated slowly and only after coordination with the anesthesiologist, and the severity of hemodynamic shifts depends on the type of occluded vessel and the level of occlusion.

If necessary, the ischemia time can be minimized using intermittent balloon occlusion (periodic deflation).

After balloon 2 is inflated, urgent interventions are performed depending on the clinical situation.

With sufficient stabilization of the patient's condition, computed tomography can be performed.

If angiocontrast is required for topical visualization of the damaged area, then balloon 2 is slightly deflated.

The balloon is deflated only by agreement with the anesthesiologist after the final or temporary stopping of bleeding by surgery or endovascular.

Rapid deflation of the inflated balloon 2 will inevitably lead to circulatory collapse; therefore, the inflation rate of the balloon is chosen 3-5 ml every 30 sec.

The extraction of the last few milliliters of fluid is the most important, since it is at this moment that blood flow is completely restored through the occluded vessel.

The moment the balloon is no longer needed, it is removed (after completely deflating).

The proposed invention was clinically tested at the Department of Military Field Surgery of the Military Medical Academy. CM. Kirov MORF of St. Petersburg and the results obtained confirmed the reliability, ease of installation of the device for temporary occlusion of the great vessels and the aorta, a significant reduction in the risk of thrombus formation, as well as a significant reduction in the time spent on surgical intervention in the patient's body (installation, extraction, etc.) )

Claims (1)

A device for temporary occlusion of great vessels and aorta, including a single-lumen catheter, at the distal end of which an inflatable balloon is installed; a J-type guide wire, consisting of a super-rigid part and a flexible part with a J-end, the flexible part being located outside the distal end of the balloon, and the super-rigid part of the guide being sealed in the lumen of the catheter; and a connector located at the proximal end of the catheter and a mechanism for inflating the balloon with a liquid connected to it, characterized in that the distal end of the inflated balloon is fixed at the end of the super-rigid part of the guidewire, and the guidewire has the ability to reciprocate relative to the catheter with a connector, and a sealing gasket is installed in the connector ...

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