RU48153U1 - SCLEROCOMPRESSOR FOR VITREORETINAL INTERVENTIONS - Google Patents

Abstract

The utility model relates to medicine, namely to ophthalmology, and can be used in vitreoretinal surgery in the treatment of proliferative diabetic retinopathy, hemophthalmus, traumatic injuries of the eyes and retinal detachments resulting from various causes. The technical result achieved by using the utility model is to ensure that the working parts of the proposed model are fully consistent with the projection site of dystophias, gaps, retinotomy borders, retinectomy, and blood clot sites at the extreme periphery when it is impossible to work in these areas without its use. The application of this invention helps to reduce the invasiveness of the operation and, thereby, reduces the time of topographic comparison of the sclerocompressor and the projection of the areas of the retina that need to be treated with a vitreotome and a laser. The technical result is achieved in that the sclerocompressor for vitreoretinal interventions contains two handles and two working parts. Both handles are made with a gradually decreasing diameter to the working part. One handle is made straight and ends with a working part made in the form of a spherical segment, the base of which is the end of the side surface of the handle. The other handle consists of two sections, straight and bent at an obtuse angle. The end of the curved section of this handle is equipped with a working part in the form of a cylinder with

rounded edges, while the axis of the cylinder forms an acute angle with the curved portion of the handle, the free ends of both handles are made rough and interconnected by a threaded connection.

Description

The utility model relates to medicine, namely to ophthalmology, and can be used in vitreoretinal surgery in the treatment of proliferative diabetic retinopathy, hemophthalmus, traumatic injuries of the eyes and retinal detachments resulting from various causes.

Known sclerocompressor used for vitreoretinal interventions. It contains a straight handle, the diameter of which gradually changes to the working part, and the working part (Storz tool catalog, p. 41, model E 5112). The working part of this sclerocompressor is made in the form of a platform with a hole in the middle in the form of an oval.

However, this sclerocompressor has a number of disadvantages. One of them is the presence of a straight handle that does not have an angle with the working part of the tool and the associated difficulty in manipulating the tool in conjunctival arches. Another disadvantage is that the working part of the sclerocompressor is not rounded and has sharp edges. Therefore, during the operation, the working part of the sclerocompressor insufficiently glides along the sclera and causes its microtraumatization. And this is accompanied by a painful reaction from the patient. In addition, the fact that in the same eye, for example, in different places, the height of the retinal detachment may not be taken into account. Be different. Therefore, with high detachments

the use of a small working platform is inefficient because it is not possible to achieve a sufficient impression shaft. An additional application of force causes an undesirable pain reaction on the part of the patient. And this leads to the fact that when removing peripherally located blood clots of the vitreous basis, excessive retinal mobility causes an increased risk of iatrogenic ruptures. All these shortcomings limit the surgeon's capabilities and force him to look for a more suitable sclero-compressor, which, in turn, increases the invasiveness of the operation and lengthens its time.

The technical result achieved by using the utility model is to ensure that the working parts of the proposed model are fully consistent with the projection site of dystrophies, gaps, retinotomy borders, retinectomy, and blood clot sites at the extreme periphery when it is impossible to work in these areas without its use. The use of this invention helps to reduce the invasiveness of the operation and, thus, reduces the time of topographic comparison of the sclerocompressor and the projection of the areas of the retina that need to be processed with a vitreotome and a laser.

The technical result is achieved by the fact that the proposed sclerocompressor for vitreoretinal interventions, containing a straight handle made with a diameter gradually decreasing to the working part and the working part, according to the utility model, the working part is made in the form of a spherical base, the base of which is the end

the side surface of the straight handle, while the sclerocompressor further comprises a handle that is made with a diameter gradually decreasing to the working part and has a straight section, and then a section curved at an obtuse angle to the straight line, the end of the curved section of this handle is equipped with a working part in the form of a cylinder with with rounded edges, the axis of the cylinder forms an acute angle with the curved portion of the handle, the free ends of both handles are made rough and interconnected by a threaded connection.

The utility model is illustrated in figures 1-3. Figure 1 shows a General view, figure 2 view A from figure 1 (enlarged), figure 3 - view B from figure 1 (enlarged).

The sclerocompressor consists of a straight handle 1, the diameter of which gradually decreases to the working part 2. The working part 2 is made in the form of a spherical segment, the base of which is located at the end of the side surface of the handle 1. The sclerocompressor also contains a handle 3, consisting of a straight and curved sections. The curved section ends with the working part 4, made in the form of a cylinder with rounded edges, the axis of which is an acute angle with the curved section of the handle 3. The diameter of the handle 3 gradually decreases to the working part 4. The ends 5 and 6 of the respective handles 1 and 3 are made rough and interconnected by a threaded connection (not shown in the drawing). The sclerocompressor can be made of stainless steel or titanium. Handles 1 and 3 have an initial diameter of 9 mm and a final diameter of 4 mm. Working part

2 is made in the form of a spherical segment, the diameter of which is 3 mm The working part 4 is made in the form of a cylinder, has a length of about 15 mm and a diameter of 6 mm.

A sclerocompressor for vitreoretinal interventions is used as follows. One of the convex working parts of the sclerocompressor is inserted into the conjunctival arch and brought to the sclera at the site of the projection of the proposed zone, for example, a retinal break. Then, as manipulations are performed in the vitreous cavity, the working part of the sclerocompressor is rolled through the sclera in the desired direction by manually moving one of the handles and its working part is set so that the center of the alleged dystrophy or rupture is located on the pressure shaft of the working part of the sclerocompressor. The working parts of the sclerocompressor alternate depending on the need. The result is a topographic comparison of the working part of the sclerocompressor with the proposed pathology zone. As a result, exact coincidence of the boundaries of the retinal pathology and the working part of the sclerocompressor is achieved, and the operation time is reduced. This ensures, on the one hand, minimal impact on the intact surrounding areas of the retina. This, in turn, firstly, increases the effectiveness of surgical treatment, and, secondly, allows you to minimize the number and severity of adverse reactions and complications from healthy eye tissues.

All this helps to increase the effectiveness of vitreoretinal intervention and reduce possible complications.

Claims (1)

A sclerocompressor for vitreoretinal interventions, comprising a straight handle made with a diameter gradually decreasing to the working part and a working part, characterized in that the working part is made in the form of a spherical segment, the base of which is the end of the side surface of the straight handle, while the sclerocompressor further comprises a handle, which made with a diameter that gradually decreases to the working part and has first a straight section, and then a section curved at an obtuse angle to a straight line, the end of the curved section This handle is provided with a working portion in the form of a cylinder with rounded edges, the cylinder axis forms with a curved handle portion an acute angle, the two free ends of the arms are roughened and are interconnected by a threaded connection.