RU66667U1 - IMPLANT FOR SURGICAL TREATMENT OF PROGRESSING AND COMPLICATED MYOPIA - Google Patents

Abstract

The utility model relates to medicine, and more specifically to ophthalmology, and can be used in the surgical treatment of progressive and complicated myopia. The implant is made of polymer elastic magnetic material with the induction of a constant magnetic field of 0.5-1 mT and has the form of a flat blade with a blade for implantation to the posterior pole of the eye and a leg for hemming the implant to the sclera, several perforation holes are made in the distal from the leg portion of the canvas, evenly spaced at least one diameter of the hole from each other and the radius of the hole from the edges of the implant. The technical result of the utility model is the stabilization of the myopic process with the simultaneous prevention of the development of dystrophic changes in the fundus or further progression, if any.

Description

The utility model relates to medicine, and more specifically to ophthalmology, and can be used in the surgical treatment of progressive and complicated myopia.

Progressive myopia continues to be one of the most urgent problems of ophthalmology, because despite the undoubted successes achieved in recent years in prevention and treatment, this disease often leads to the development of irreversible changes in the fundus and a significant decrease in vision at a young working age. With the progression of the process, the scleral membrane is stretched, its strength properties decrease and, as a result, circulatory disorders in the vascular system of the eye, including in the posterior ciliary arteries. This is one of the links in the pathogenesis of chorioretinal dystrophies.

Recent studies have shown that with progressive myopia, more than 40% of children and adolescents develop complications - peripheral and even central dystrophies, the frequency of which increases significantly with increasing age, degree of myopia and its duration (EP Tarutta. Sclero-strengthening treatment and prevention of complications of progressive myopia in children and adolescents: Abstract of thesis, MD, MD - M., 1993. - 51 p.).

The most effective methods of treating progressive myopia are surgical sclerotherapy.

Known biological implants for the surgical treatment of progressive myopia: auto- (Broshevsky T.N., Panfilov N.I. Meridional strengthening of the sclera with wide fascia of the thigh with progressive myopia // Bulletin of Ophthalmology. - 1970. - No. 2. - P. 19-23 .), allo- (Fedorov S.N., Ivashina A.I., Balashova N.Kh., Kuznetsova N.P. Prevention of progressive myopia by the method of scleroplasty:

Guidelines. - M., 1991. - P.8.) (Including brepho- (Zaykova M.V., Lyalin A.N. Brephoscleroplasty with progressive myopia // Ophthalmol. Journal. - 1984. - No. 8. - P. 463-467)), xeno-tissue (Cheglakov V.Yu. Xenoscleroplasty of the posterior pole of the eye in the treatment of patients with progressive myopia: Dis ... Ph.D. - M., 2006. - P.41-44.) . The disadvantages of these materials are: difficulties in obtaining (associated with the lack of a clear legislative framework for the removal of cadaver organs and tissues) and processing, moral and ethical and religious restrictions on their use, as well as the replacement of biological material with the connective tissue of the recipient over time, which reduces the stabilizing effect of the operation .

Synthetic implants for surgical treatment of progressive myopia are known: teflon (Tarutta E.P., Iomdina E.N., Andreeva L.D., Markosyan G.A. Morphological features of the engraftment of synthetic transplants after scleroplasty in the experiment // Herald of Ophthalmology. - 1999 . - No. 3. - P.16-17.), Mercilene (Tarutta E.P., Iomdina E.N., Andreeva L.D., Markosyan G.A. Strengthening of the sclera with new types of synthetic materials with progressive myopia // Bulletin of Ophthalmology . - 1999. - No. 5. - P.8-9.), Scleracode (Tarutta E.P., Iomdina E.N., Andreeva L.D., Mar Kosyan, G.A. Morphological features of the engraftment of synthetic grafts after scleroplasty in an experiment // Herald of Ophthalmology. - 1999. - No. 3. - P.16-17.), metal implants (copyright certificate No. 1114417), silicone rubber (these implants are taken for prototype) (Utkin V.F. Siliconoscleroplasty with progressive myopia in children and adolescents // Bulletin of Ophthalmology. - 1987. - No. 3. - P.54-56.). Disadvantages of synthetic implants: do not have a biologically active effect on the membranes of the eye, in some cases, the implant may be displaced; upon completion of revascularization, the metabolic effect of the operation using synthetic implants is reduced, which does not exclude further progression of the dystrophic process, despite the stabilization of the anatomical and topographic parameters.

The objective of the utility model is to create a synthetic implant for the surgical treatment of progressive and complicated myopia, which has a long biologically active effect.

The technical result of the utility model is the stabilization of the myopic process with the simultaneous prevention of the development of dystrophic changes in the fundus or further progression, if any.

The technical result is achieved due to the fact that the weak constant magnetic field of the implant (0.5-1 mT) improves the microcirculation of the surrounding tissues, stimulates the development of new vessels (which positively affects the hemodynamics in the implantation zone), has a local tissue effect, promotes the formation of connective tissue -woven capsule around the implant; through the perforations in the implant web, the growth of connective tissue and newly formed vessels occurs, which in combination with the formation of a fibrous capsule around the implant leads to the formation of a single “sclera-implant” complex and has a sclero-strengthening effect; the shape of the implant in the form of a flat blade with a blade and leg is optimal for achieving a technical result and convenient for implantation.

The implant has the form of a flat scapula 16 mm long and 1.0 mm thick, with a web 13 mm long and an area of 80-170 mm ² intended for implantation to the posterior pole of the eye, and a leg up to 2 mm wide and 3 mm long, designed for hemming implant to the sclera. The implant web may have a round, or oval, or rectangular, or square, or trapezoid shape, for example, an isosceles. Rectangular, square, trapezoidal web can be made with rounded corners for easy implantation. In the distal (from the leg) part of the web, several perforation holes with a diameter of 1 mm are made evenly spaced at least one hole diameter from each other and the radius of the hole from the edges of the implant. Distal area

the implant web with perforations can be, for example, up to 1/3 of the total area of the implant web. The implant leg may be, for example, semi-oval or rectangular. The rectangular leg can be made with rounded corners.

The implant is made of a synthetic polymer elastic magnetic material, consisting of a polymer elastic base (biostable polymer based on polyacrylate, vinyl polymer or silicone rubber) and magnetic filler. Powdered particles of the magnetic filler of the samarium-cobalt or neodymium-iron-boron system are uniformly distributed in the polymer elastic material. The implant is coated with a hydrogel or collagen membrane; magnetically reversed, the magnitude of the induction of a constant magnetic field of the implant is 0.5-1.0 mT.

Scleroplastic surgery using the proposed implant is performed as follows. For patients under 14 years of age, surgery is performed under general anesthesia (Sol. Thiopentalinatrii 1-2%). For patients over 14 years old, the operation was performed under local anesthesia (installation of a 2% solution of dicain in the conjunctival cavity). In the upper outer quadrant, departing from the limb by 6 mm, cuts of the conjunctiva and tenon membrane are 8-9 mm long. Using a spatula, a tunnel is formed towards the posterior pole of the eye so that the proposed implant fits freely. The implant is immersed under the tenon membrane with the distal part to the posterior pole of the eye and fixed to the sclera 10 mm from the limbus by the leg. The operation is completed by suturing the conjunctiva and the introduction of an antibiotic under it.

The utility model is illustrated by figure 1. Figure 1 shows an implant with a web 1 in the form of an isosceles trapezoid, perforations 2 in the distal part of the web and a rectangular leg 3.

The utility model is illustrated by the following data.

Extrascleral implantation of the proposed implants was performed for 5 Chinchilla rabbits (experimental group). In the control group (5 rabbits), scleroplastic material of a similar structure without magnetic properties was implanted. At various times, the animals of both groups were studied blood flow indicators by laser Doppler flowmetry (LDF). Changes in blood flow indices obtained by the LDF method were more pronounced and lasting in the eyes of the experimental group (an increase of 20-25% compared to the preoperative level and indicators in the control group 6 months after implantation), which suggests a long-term improvement in microcirculation under the influence constant magnetic field of the proposed implant in the surrounding tissues.

According to a histomorphological study (period 6 months after surgery) in experimental animals of both groups, the development of an aseptic inflammatory reaction was observed, which was accompanied by vascularization and the formation of a connective tissue capsule around the implant. However, in the experimental group, the degree of vascular changes was more pronounced, which was manifested by a large number of newly formed vessels and the diameter of the vascular bed.

The utility model is illustrated by the following clinical example.

Patient N., 14 years old. Diagnosis: progressive myopia of a high degree of OU. He complained of a gradual decrease in vision, starting from 9 years old. Significant visual impairment notes over the past year.

Visual acuity OD 0.04 sph - 6.5 = 0.8

OS 0.04 sph - 6.5 = 0.8

PZO OD 25.9 mm

OS 26.1 mm

Sclera thickness according to B-scan data OD = 0.55 mm; OS = 0.6 mm.

ERG. Indices of electroretinograms for white light show a decrease in the amplitude values “a” and “b” of waves: wave “a” = 40 μV; wave "in" = 69 μV.

When examining the peripheral parts of the fundus of the sites of retinal dystrophy was not detected.

A scleroplastic operation was performed using the proposed implant in the form of a flat scapula 16 mm long and 1.0 mm thick, with a rectangular blade 13 mm long and an area of 150 mm ² and a rectangular leg up to 2 mm wide and 3 mm long. In the distal (from the leg) part of the web, 6 perforation holes with a diameter of 1 mm are made evenly spaced at least one hole diameter from each other and the radius of the hole from the edges of the implant. The area of the distal part of the implant web with perforations is 1/3 of the total area of the implant web. Magnetic filler - niodim-iron-boron systems. The magnitude of the induction of a constant magnetic field of the implant is 0.5 MT.

1.5 years after surgery:

Visual acuity OD 0.05 sph - 6.5 = 1.0

OS 0.05 sph - 6.5 = 1.0

PZO OD 25.8 mm

OS 26.0 mm

ERG. Indices of electroretinograms for white light show an increase in the values of the amplitude “a” and “b” of the waves: wave “a” = 43 μV; wave "in" = 74 μV.

When examining the peripheral parts of the fundus, the state of the retina is unchanged.

The thickness of the complex "sclera-implant" according to the B-scan: OD = 1.6 mm; OS = 1.7 mm.

Scleroplastic surgery with the proposed implants was performed in 8 patients (13 eyes). The implants were made of synthetic

polymer elastic magnetic material consisting of a polymer elastic base (biostable polymer based on polyacrylate, vinyl polymer or silicone rubber) and a magnetic filler of the samarium-cobalt or neodymium-iron-boron system. The magnitude of the induction of a constant magnetic field of the implants ranged from 0.5 to 1.0 MT. Implants were used in the form of a flat scapula 16 mm long and 1.0 mm thick with a round, or oval, or rectangular, or square, or trapezoidal web 13 mm long and an area of 80 to 170 mm2 and a semi-oval or rectangular leg up to 2 wide mm and a length of 3 mm. In the distal (from the leg) part of the implant web, 3 to 6 perforation holes with a diameter of 1 mm were made uniformly spaced at least one hole diameter from each other and the radius of the hole from the edges of the implant. The area of the distal part of the implant web with perforations amounted to 1/3 of the total web area.

In all cases, stabilization of visual functions and PZO parameters, the absence of dystrophic changes on the periphery of the retina were noted.

Claims (3)

1. An implant for the surgical treatment of progressive and complicated myopia from synthetic material, characterized in that it is made of a polymer elastic magnetic material with a constant magnetic field induction of 0.5-1 mT and has the form of a flat scapula with a blade for implantation to the posterior pole of the eye and a leg for stitching the implant to the sclera, several perforation holes are made in the distal from the leg part of the web, evenly spaced at least one hole diameter from each other and the hole radius TIFA from the edges of the implant. 2. The implant according to claim 1, characterized in that it has a length of 16.0 mm, a thickness of 1.0 mm, its canvas has a length of 13 mm and an area of 80-170 mm ² , the dimensions of its legs: width up to 2 mm and length 3 mm, the diameter of the through perforations is 1.0 mm, and the area of the distal part of the implant web with perforations is up to 1/3 of the total area of the implant web. 3. The implant according to claim 1 or 2, characterized in that the implant leg has a semi-oval or rectangular shape, the implant web has a round, or oval, or rectangular, or square, or trapezoidal shape, and a rectangular, square, trapezoidal web can be made with rounded corners.