RU138605U1 - OVER WEIGHT CORRECTION DEVICE - Google Patents

Abstract

An overweight correction device comprising an elastic balloon in which a valve assembly is mounted, characterized in that the elastic balloon is made of rubber based on silicone rubbers selected from the group polydimethylphenyl vinyl siloxane, polymethyl vinyl trifluoropropyl siloxane, the valve assembly is made up of a hollow body having a side cylindrical wall and blank bottom, and a flange that is mounted on the outside of the container and hermetically connected to the proximal part of the body, and the flange is made with a hole thia, coaxial with the body, and the proximal part of the body, designed to receive the tip of the discharge tube inserted into the body through the hole in the flange, is made of silicone rubber with Shore A hardness of 60-70 units, while the distal part of the valve body is made of silicone rubber with Shore A hardness of 20 ÷ 45 units, containing 10-15% polydimethylsiloxane fluid, and a cut is made on the side wall or the bottom of the distal part of the body, which can open when def formation of the distal part of the body under the influence of working fluid pressure in the process of filling the balloon.

Description

The utility model relates to medical equipment, in particular, to implantable devices designed to treat obesity and correct overweight.

Obesity is a serious medical problem affecting millions of people around the world.

One type of alternative treatment for overweight is a conservative technique - the installation of an intragastric balloon. Currently, the cylinder is the simplest and most reliable means of weight loss for the patient.

The essence of the method is to place a special balloon in the stomach under endoscopic visual control and then fill the balloon with physiological saline 400 ÷ 700 mm.

Filling part of the volume of the stomach, the balloon promotes earlier saturation during meals, and due to quantitative restrictions on food, the patient loses weight.

At the same time, the inflated balloon, stretching the wall of the stomach, causes irritation of satiety receptors, which leads to an early feeling of satiety.

A device for correcting excess weight is known [US Pat. No. 4,133,315], which is inserted into the lumen of the stomach through the nasal or oral cavities. The device is an elastic tensile shell in the form of a ball, firmly connected to the discharge line to fill the shell with physiological saline. The inflated balloon remains connected to the filling means for the entire period of time it is in the stomach, which allows you to maintain a constant volume of fluid into the balloon through the tubes leaving the nose. Similar intragastric cylinders are described in US Pat. No. 5,234,454.

However, the presence of such tubes creates discomfort and significant inconvenience for the patient when using such devices.

Also known devices for changing the volume of the stomach, including a flexible balloon of a spherical shape with a valve assembly in the form of a longitudinal groove, designed to fill and remove the working fluid [RF patent RU 2269943, US patent US 4416267, US patent US 4485805].

The discharge line is connected to the valve node through a special tip, and after filling the gastroballon, the discharge line is removed from the stomach.

A significant drawback of the proposed solutions is the high probability of decompression of the valve due to mechanical damage to its walls after filling the cylinder with a working fluid and removing the discharge line tip from the valve body. This causes a leak in the valve and leakage of fluid from the cylinder.

Other prior art designs of valve devices used in implantable devices and described in US Pat. Nos. 6,416,999 (diaphragm valve), 5,599,3277 (mechanically actuated valve, 5,916,198 (gas valve), are quite complex. , laborious to manufacture and do not provide sufficient reliability during operation.

Closest to the proposed technical solution is a device to reduce the volume of the stomach, including an elastic inflated balloon made of a polymer material and a valve and a valve attached to the shell of the balloon [US patent US 508406]. The duck nose valve includes two flat silicone plates connected at the edges and glued to the end of the valve. During the installation of the ball, a plastic tip at the distal end of the discharge tube enters the valve through the hole in the end of the flange, expanding it and thus allowing pumping or removal of the working fluid from the cylinder.

A significant drawback of the closest solution analogue is the leakage of fluid from the ball due to deformation or even rupture of the valve flaps when installing or removing the tip. During storage of the device, sticking of the working surfaces of the silicone valve is possible, which complicates, and in some cases makes it completely impossible to carry out the procedure of filling the ball with liquid.

In addition, silicone rubbers used in the manufacture of the membrane of the intragastric balloon have low resistance to the effects of gastric contents - acids and enzymes, which reduces the reliability of such devices. At the same time, the high gas permeability of the materials used contributes to the migration of the working fluid through the walls of the cylinder, leading to deflation of the ball and the passage of the deflated device through the gatekeeper. This leads to bowel obstruction and requires surgical intervention.

This useful model is aimed at solving the problem of creating a reliable device at all stages of the operation, which, with the simplest construction possible, has the optimal interaction of the balloon with the surrounding tissues of the stomach.

The device for correcting excess weight contains, like the closest analogue, an elastic inflated balloon made of silicone rubber and having an opening in which the valve assembly is installed. The difference between the claimed device and the closest analogue is that the cylinder is made mainly of modified siloxane elastomers, the valve assembly is made up of a hollow body shaped like a body of revolution with a side wall and a blind bottom, and a flange that is mounted on the outside of the cylinder and hermetically connected with the proximal part of the body, and the flange is made with a hole coaxial to the body, and the proximal part of the body is designed to receive the tip of the discharge tube inserted into the bladder through the hole in the flange is made of silicone rubber with a shore hardness A - 60 ÷ 70 units, while the distal part of the valve assembly body is made of silicone rubber containing polydimethylsiloxane liquid, with a shore hardness A - 20 ÷ 45 units, on the side a longitudinal section (slot) is made into the wall of the distal part of the body — a slit valve capable of opening upon deformation of the distal part of the body under the influence of the working fluid pressure in the process of filling the cylinder. The cut can also be made only in the bottom of the distal part of the body or at the same time in the bottom (in the radial direction) with approach in the form of a longitudinal (along the generatrix of the cylindrical surface) on the side surfaces of the distal part of the body.

The technical result from the use of the utility model is to increase the reliability and durability of the device by eliminating the loss of the working fluid filling the cylinder through the valve assembly, which is achieved by protection against deformation of the distal part of the valve assembly housing and increasing the shelf life of the device due to the prevention of adhesion of the walls of the cut (slotted valve) ), increasing the resistance of the valve to the effects of gastric contents. The execution of the valve body body in the form of a hollow body of rotation of silicone rubber of various compositions and with different hardness, namely, in the proximal part of silicone rubber with a shore hardness of A 60 ÷ 70 units, and in the distal part of silicone rubber with hardness according to Shore A, 20–40 units, into which 10–15% of polydimethylsiloxane liquid is introduced, allows to avoid leakage of liquid from the cylinder and thereby increase the reliability and durability of the slotted valve, since the sealing in the valve is created by contact voltage on top contact surfaces of the groove, which is mainly determined by the elastic properties of rubber. The elastic modulus of silicone rubber with a shore hardness of A 20 units 50% more elastic modulus of rubber with shore hardness A 60 units

The decompression of the valve occurs when the amount of elasticity of the rubber is insufficient to create stress in the contact zone, providing the necessary tightness.

The presence of 10 ÷ 15% polydimethylsiloxane fluid in the rubber helps to prevent the walls of the groove from sticking together due to fluid migration to the contacting surfaces of the cut (slotted valve).

The implementation of the proximal part of the valve body housing of silicone rubber with a hardness of 60 ÷ 70 units allows you to protect the distal part of the body, in which the incision is made - a slit valve from deformation during assembly of the device, as well as to increase the reliability of the node when introducing the tip of the discharge line when filling the cylinder with a working fluid.

An additional technical result from the use of the device is the use of modified siloxane elastomers as the basis for the manufacture of the balloon shell, which makes it possible to increase the resistance of the balloon to aggressive stomach contents and to reduce the permeability of the working fluid through the walls of the balloon (see table 1).

As can be seen from the data shown in table 1, the use of modified rubbers for the manufacture of the shell of the balloon can significantly increase the resistance to acid and significantly reduce the permeability of the walls of the balloon and, accordingly, the loss of fluid.

The utility model is illustrated by drawings, which depict:

In FIG. 1 - device for correcting excess weight in the working position.

In FIG. 2 - valve assembly of the device (option in a longitudinal section on the side surface or with a radial section in the bottom when the section enters the side surfaces).

In FIG. 3 - tip of the discharge line.

In FIG. 4 is a general view of the device prepared for installation.

The device for correcting excess weight 1 consists of an elastic balloon 2 formed by a rubber sheath 2 based on a modified siloxane elastomer (for example, polydimethylphenylmethylvinylsiloxane or polymethylvinyltrifluoropropylsiloxane rubber) and valve assembly 4 (Fig. 2), which consists of a cylinder 2 which is tightly fixed to the outer surface of the cylinder 3 with a body 5 connected to it from the inside of the balloon, made in the form of a body of revolution, having a lateral cylindrical wall and a blind bottom located with orons opposite the connection of the housing 5 with the flange 3.

The flange 3 of the valve assembly is made with a hole 6, coaxial to the housing 5. The hole 6 serves to receive the tip 10 of the discharge line 13 and pass it inside the housing 5 when filling the cylinder 2 with a working fluid. The flange 3 is hermetically connected to the housing 5, the cavity 9 of the proximal part of which is designed to accommodate and fix the tip 10 of the discharge line 13.

The distal part of the valve assembly body 5 is made of silicone rubber with a hardness of 20–40 units, while 10–15% of polydimethylsiloxane liquid is introduced into the silicone rubber composition. A longitudinal section 8 is made on the lateral surface of the distal part of the casing 5, forming a slit valve that can open when the distal part of the casing 5 deforms under the influence of the working fluid pressure when filling the cylinder 2. The cut can also be made in the bottom of the distal part of the casing in the radial direction or simultaneously in bottom approaching the side surfaces of the distal part of the body longitudinally along the guide cylindrical side surface (not shown in the drawings).

Installation of a device for correcting excess weight in the patient’s stomach is as follows.

The balloon 2 in an undisturbed state is placed in a thin-walled destructible shell 15. A pressure line 13 with an overpressure source (not shown) is connected to the valve assembly 4 by means of a tip 10.

The tip 10 through the hole 6 of the flange 3 is introduced by the inlet part 14 into the cavity 9 of the housing 5 of the valve assembly, while the ledge 16 of the tip 10 abuts the outer end of the flange 3, restricting its movement inside the housing 5. The shape of the tip 10 (with protrusions on the side surface) is held from falling out of the valve assembly in the process of filling the cylinder with working fluid.

The device is installed under endoscopic control and with complete anesthesia of the patient. Before installation, the thin-walled destructible shell 15 is lubricated with a special gel.

Methylene blue dye is introduced into the container with a liquid (for example, water) intended for inflating the balloon 2, which is necessary for determining the leakage of the liquid from the balloon 2 in case of its depressurization. Next, the device is inserted through the esophagus into the lumen of the stomach. An overpressure source (for example, a syringe) is connected to a discharge line 13 connected to the cylinder 2 by means of a tip 3 through an adapter 14. Under the influence of excess pressure, the distal part of the housing 5, made of silicone rubber of lower hardness, begins to deform, the edges of the cut 8 (slotted valve) diverge, an opening is formed through which the cavity of the cylinder 2 is gradually filled with working fluid.

Thin-walled destructible shell 15 under the influence of an inflated balloon 2 is broken, and the cylinder 2 is completely released.

Filling of the cylinder 2 with a working fluid is carried out under constant visual control (through a gastroscope).

After the cylinder 2 is filled with the required volume of liquid, for example, in an amount of 500 ml, the pressure of the liquid is removed, while the edges of the section 8 converge, the slit valve closes. The discharge line 13 is pulled outward, while the tip 10 exits the valve assembly 4. The discharge line 13 and the gastroscope are removed from the patient's esophagus, and the installation procedure for the device ends. Ballon 2 remains in the lumen of the stomach.

Ballon 2 can be in the patient’s stomach for up to 6 months.

The balloon is removed under complete anesthesia by puncture of its membrane and suction of the liquid. Then, using a special tool (endoscopic forceps), balloon 2 is removed from the patient’s stomach.

Table 1 Sheath material The exposure time in an environment with pH = 1.2 1 month 3 months strength change,% elongation change weight loss% strength change,% elongation change weight loss% 1. Polydimethylmethylvinylsiloxane rubber SKTV- -10 -twenty 2.1 -25 -thirty -5.2 2. Polydimethylphenylmethylvinylsiloxane rubber SKTFV-803 -1.8 0 -3.4 -6.0 0.6 3. Polymethylvinyl trifluoropropylsiloxane rubber -1.5 1,0 0 -2.2 -4.8 0.6

Claims (1)

An overweight correction device comprising an elastic balloon in which a valve assembly is mounted, characterized in that the elastic balloon is made of rubber based on silicone rubbers selected from the group of polydimethylphenyl vinyl siloxane, polymethyl vinyl trifluoropropyl siloxane, the valve assembly is made up of a hollow body having a side cylindrical wall and blank bottom, and a flange that is mounted on the outside of the container and hermetically connected to the proximal part of the body, and the flange is made with a hole thia, coaxial with the body, and the proximal part of the body, designed to receive the tip of the discharge tube inserted into the body through the hole in the flange, is made of silicone rubber with Shore A hardness of 60-70 units, while the distal part of the valve body is made of silicone rubber with Shore A hardness of 20 ÷ 45 units, containing 10-15% polydimethylsiloxane fluid, and a cut is made on the side wall or the bottom of the distal part of the body, which can open when def formation of the distal part of the body under the influence of working fluid pressure in the process of filling the balloon.

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