RU18232U1 - DEVICE FOR DRAINING IN-EYE-EYE FLUID IN GLAUCOMA - Google Patents

Abstract

1. Device for draining intraocular fluid, consisting of a housing forming a chamber with inlet and outlet channels and a tube installed in the inlet of the housing, characterized in that an annular protrusion covering the inlet channel is made in the chamber cavity, while the device is equipped with an elastic membrane fixed in the cavity of the chamber, overlapping the outlet opening of the inlet channel and made with holes located outside the area of contact with the annular protrusion, while the membrane is made with the possibility tight fit to the annular protrusion. 2. The device according to claim 1, characterized in that it is made with a distribution plate, onto which the outlet channel of the housing.

Description

The utility model relates to medicine, in particular, to ophthalmology, and can be used for a controlled outflow of intraocular fluid (HPW) in the treatment of patients with glaucoma.

Known drainage device for the removal of VGZ, consisting of a silicone tube and a plate made of silicone rubber filled with barium sulfate (see Lloyd MA, Baerveldt. Ophthalmology 1994-Vol. 101. No. 8, p. 1456-1464) .

A significant drawback of the proposed solution is the lack of a device that regulates the outflow of HPV and, as a result, the occurrence of postoperative hypotension (dehydration of the intraocular chamber).

Closest to the proposed is a device for draining the HPW from the cavity of the eye, consisting of a camera and a tube connected to it (see Thomas C. Vhite, US patent No. 4554918). This device provides the flow of the HPW in only one direction: from the intraocular chamber to the external collection vessel. When the container is filled, the patient compresses it to push the accumulated hepatitis C back into the body, where it is adsorbed

However, this device has a significant drawback - in order to push out the accumulated VGZ in the collection vessel for its subsequent adsorption, the patient is forced to compress the container manually. In addition, one of the complications developing when using this device with glaucoma treatment is blockage of the slit valve at the end of the tube, as a result of protein deposition on the valve surface.

The problem solved by this useful model is to increase the efficiency of drainage of intraocular fluid and increase convenience for the patient.

The technical result when using this utility model is the absence of blockage of the inlet channel due to protein deposition due to a change in the design of the inlet valve: the opening of a round (or other) section is blocked by an elastic membrane, squeezed out when the intraocular pressure is raised.

The problem is achieved with the achievement of the specified result due to the fact that in the device for drainage of intraocular fluid, consisting of a housing forming a chamber, with inlet and outlet channels and a tube installed in the inlet of the housing, an annular protrusion is made in the chamber cavity, covering the inlet channel while the device is equipped with an elastic curved membrane fixed in the cavity of the chamber, overlapping the outlet of the inlet channel and made with holes located outside the region ty contact with the annular protrusion, while the membrane is made with the possibility of tight fit to the annular protrusion.

In addition, the device is made with a distribution plate, onto which the vent channel of the housing is brought out.

The presence in the proposed device of the camera with an elastic membrane provides a monitored and unidirectional current IHF, thereby increasing the efficiency of drainage and reducing the number of complications.

The utility model is illustrated by drawings, where the figure shows the appearance of the claimed device.

The device includes a housing 1 with an inner chamber 2 and a distribution plate 3. The chamber 2 is formed by a lower flat wall 4 of the housing 1, made in one piece with the distribution plate 3, and an elastic wall 5 made in the interior of a convex curved surface attached to bottom wall 4 of the housing.

In the housing 1 are made inlet 6 and outlet 7 channels for VGZH. A silicone tube 8 is inserted into the inlet channel 6 of the chamber. To place the C. dicon tube 8 in the chamber, a tubular guide 9 is made on the bottom wall 4 of the housing 1. The tubular guide 9 is 90 ° angled, as a result of which the cornea 1 inside chamber 2 is formed by an annular protrusion 10, oriented perpendicular to this wall 4. The hole 11, covered by the annular protrusion 10, communicates the ventilation duct 6 of the cornea 1 with the NOL of the chamber 2.

The exhaust channel 7 is made in the form of an opening in a curved elastic wall 5 and communicates the nullity of the chamber 2 with the outer space. As a result, the conclusion of the HPW on the distributive Nlastin 3 is discouraged.

The distribution plate 3 serves to accelerate the adsorption of intraocular fluid. Distributive nlastina 3 is filled with a predominantly flat shape and is limited at the edges by the sides 12. Structurally, the distribution nlastina is a continuation of the lower flat wall of the cornea.

An elastic membrane 13 is located inside the cavity of the chamber 2, forming a curved surface, convex inside the chamber 2 and adjacent to the annular protrusion 10. The elastic membrane 13 is hermetically attached along its perimeter to the upper part of the inner surface of the elastic non-linear convex chamber wall 5.

Holes 14 are made on the membrane 13, located outside the area of contact with the annular protrusion 10. The holes 14 are used to equalize the pressure inside the volume limited by the membrane 13 and the ambient pressure. The membrane 13 is made in such a way that under normal intraocular pressure it fits snugly in the central zone of the curved surface to the annular protrusion 10.

The proposed device operates as follows.

The device is attached to the sclera in one of the quadrants of the eyeball, between the rectus muscles.

A silicone tube 8, fixed in the input channel 6 of the device, is inserted into the anterior chamber through an opening in the fibrous capsule of the eye.

Depending on the fluid pressure in the chamber 2, determined by intraocular pressure, the curved elastic membrane 13 is either pressed against the annular protrusion 10 (in the case of normal pressure) and blocks the current

the intraocular fluid through the opening 11 of the inlet channel 6 into the nullity of the chamber 2, or under the influence of intraocular pressure is squeezed from the annular protrusion 10, which creates the possibility of outflow of fluid and forms a one-way flow of intraocular fluid through the opening 11 into the cavity of the chamber 2 and further out through the outlet channel 7 on distribution plate 3.

By changing the parameters of the membrane 13 (for example, the radius of curvature), it is possible to vary the force of its pressing against the annular protrusion 10, thereby varying the pressure at which the outflow of the HPW occurs without any noticeable resistance to flow.

Since the anti-inflammatory agent can be absorbed in the patient’s body only gradually, the presence of the distribution plate 3 in the proposed device accelerates this process, since the anti-inflammatory agent is distributed over a relatively large surface.

Claims (2)

1. Device for draining intraocular fluid, consisting of a housing forming a chamber with inlet and outlet channels and a tube installed in the inlet of the housing, characterized in that an annular protrusion covering the inlet channel is made in the chamber cavity, while the device is equipped with an elastic membrane fixed in the cavity of the chamber, overlapping the outlet opening of the inlet channel and made with holes located outside the area of contact with the annular protrusion, while the membrane is made with the possibility tight fit to the annular protrusion. 2. The device according to claim 1, characterized in that it is made with a distribution plate, onto which the outlet channel of the housing.