RU2325884C2 - Method of peripheral retinal ruptures treatment complicated with vitreal traction and subclinical retinal detachment - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention belongs to medicine field, particularly to ophthalmology and can be used in treatment of peripheral retinal ruptures complicated with vitreal traction and sub clinical retinal detachment. Treatment is carried out in three phases. In the first phase they perform operation with argon or diode laser within intact retina until obtainment of closed contour of coagulation. Second phase consist of conduction of retinotomy "uvula" of retinal valve by Nd:YAG laser by phased fragmentation of "uvula", starting from the top of rupture. In 2-3 days after retinotomy in the case of occurrence of retinal detachment the third phase is conducted - it is transscleral infrared diode laser retinopecksy under visual biomicroscopic control. This method provides increase of effectiveness of treatment and decrease of aftereffect by preventing progression of rupture and retinal detachment, reliable removal vitreal traction and resorption of subretinal liquid.

EFFECT: increase of effectiveness of treatment of complicated peripheral retinal ruptures and decrease of aftereffect.

4 cl, 1 ex

Description

The present invention relates to the field of medicine, namely to ophthalmology.

With the early detection and timely treatment of various types of peripheral vitreochorioretinal dystrophies, laser retinal coagulation is a common means of preventing retinal detachment, although there is evidence of insufficient effectiveness in evaluating the long-term results of treatment.

Known methods of treatment by laser vitreolysis of traction and retinal membranes (see Puliafito CA, Wasson PJ, Steinert RF et al. Nd-YAG laser surgery on experimental vitreous membranes. Arch. Ophthalmol 102, 1984. - P.843-847, and Berlin L, Stenkula S, Crafoord S et al. A new technigue of treating rhegmatogenous retinal detachment using the Q-switched Nd-YYAG laser. Ophthalmic Surg, 1987. - 18. - P.890-892).

The closest is the treatment method in which the laser action is carried out in the form of continuous closed or open circuits in a shape similar to the shape of a pathologically changed tissue site, while the effect is performed within healthy tissue (see RF patent No. 2114585, 1998).

However, according to known methods of traction, they are cut off once, without achieving the desired treatment effect, complications in the form of changes in the vitreous body and hemorrhage are possible.

The technical result of the treatment of peripheral retinal ruptures is to increase the effectiveness of treatment by inhibiting the progression of rupture and detachment of the retina, reliable elimination of vitreous traction, and also reducing intra- and postoperative complications.

New in achieving the technical result is that they perform laser irradiation with an argon or diode laser within the intact retina until a closed coagulation loop is obtained.

Also new is the fact that the retina is exposed to the Nd: YAG laser by phasing the fragmentation of the “tongue” of the retinal valve, starting from the top of the gap until there is no movement of the clipped portion of the “tongue” of the retinal valve to the plane of the retina.

Also new is the fact that, after 2-3 days, transsclerical infrared diode retinopexy is performed under visual biomicroscopic control.

Also new is the fact that laser irradiation with an argon or diode laser is carried out at a wavelength of 485-530 nm, a radiation power of 200-300 mW, a spot size in the focal plane of 300-500 microns; the exposure power of the Nd: YAG laser is 3-8 mJ at an exposure time of 10 ^-9 sec; transcleral infrared diode retinopexy is carried out at a wavelength of 810 nm, exposure power 800-1200 mW, exposure exposure up to 3.5 seconds.

Performing laser irradiation with an argon or diode laser along the edge of the gap until a closed loop is obtained provides reliable delimitation of the zone of rupture or detachment of the retina, preventing the further spread of rupture and detachment of the retina.

Retinotomy by an Nd: YAG laser with an energy of 3-8 mJ per pulse with an exposure of 10 ^-9 seconds ensures the elimination of the effect of traction from the vitreous body on the retina.

Conducting transscleral infrared diode retinopexy under visual biomicroscopic control with a wavelength of 810 nm, a power of 800-1200 mW, exposure of up to 3.5 seconds promotes resorption of the subretinal fluid and ensures the formation of a chorioretinal adhesion. All this increases the effectiveness of treatment and the reduction of intra- and postoperative complications.

Comparative analysis with the prototype shows that the proposed method differs from the known one in that they perform laser irradiation with an argon or diode laser within the intact retina until a closed coagulation loop is obtained, followed by exposure to the retina with an Nd: YAG laser by stagewise fragmentation of the “tongue” of the retinal valve, starting from the top of the gap to the lack of movement of the cut off tissue in the vitreous body and changes in the angle of deviation of the “tongue” of the retinal valve to the plane of the retina, e 2-3 days carried transscleral infrared diode retinopexy biomicroscopic under visual control, the laser irradiation argon or a diode laser is carried out at a wavelength of 485-530 nm, emission 200-300 mW power, spot size at the focal plane of 300-500 microns; the exposure power of the Nd: YAG laser is 3-8 mJ at an exposure time of 10 ^-9 sec; transscleral diode retinopexy is carried out at a wavelength of 810 nm, an exposure power of 800-1200 mW, an exposure time of up to 3.5 seconds, which meets the criterion of "novelty."

A new set of features provides an increase in the effectiveness of treatment by inhibiting the progression of rupture and detachment of the retina, reliable elimination of vitreous traction and reducing intra- and postoperative complications due to laser exposure under visual biomicroscopic control.

The method is as follows.

In addition to the standard ophthalmologic examination, all patients undergo β-scanning, optical coherence tomography, and dynamic video and photo recording. On the schematic map the sizes, localization, ratio of the retinal rupture and the area of the retinal detachment to the retinal vessels, the parameters of laser exposure are noted. At the first stage, after standard premedication, laser coagulation is performed by radiation of an argon or diode laser within the intact retina until a closed coagulation loop is obtained with the intensity of exposure according to the classification of F.A.L'Esperance 2-3 degrees. The size of the exposure spot in the focal plane is 300-500 microns, the radiation power is 200-300 mW, and the wavelength is 485-530 nm. Then, a retinotomy of the tip of the “tongue” of the valve rupture is performed with an Nd: YAG laser with an energy of 3-8 mJ per pulse with peripheral sclerocompression and the use of a Goldman contact lens. The elimination of traction effects is achieved by dosed stepwise fragmentation of the “tongue” of the retinal valve, and the criterion for the sufficiency of retinotomy is the lack of subsequent displacement of the cut site in the vitreous body, partial or complete fit of the retinal valve and a change in the angle of its deviation to the plane of the retina. 2-3 days after retinotomy, transscleral infrared diode retinopexy is performed using radiation with a wavelength of 810 nm through a fiber optic with a DioPexy tip (OcuLight) with a radiation power of 800-1200 mW, the exposure is not more than 3.5 seconds under visual biomicroscopic control until the blanching is visible the retina. This stage of treatment provides the formation of a chorioretinal adhesion and promotes the resorption of subretinal fluid.

The method is illustrated by the following clinical example. Patient U. was treated with a diagnosis of operated grade 3 myopia, peripheral “valve” retinal rupture complicated by vitreous traction, posterior vitreous detachment of both eyes, partial hemophthalmus of the right eye.

He complained of "flashes" and floating haze in sight. 2 weeks ago, he was treated on an outpatient basis (at the place of residence) for partial hemophthalmus.

Localization of retinal breaks in the upper external segments (10-11 hours of the right eye and 1-2 hours of the left) on the middle periphery of the fundus. A zone of local retinal detachment without a line of self-restriction was determined along the edge of the gap, the edges of the gap were raised above the retina plane, the “tongue” of the valve gap was directed by the apex into the eyeball cavity, pronounced vitreous traction. When the eyes moved, the “tongue” of the gap fluctuated in the direction of displacement of the vitreous body; according to the ultrasound β-scan, a detachment of the hyaloid membrane was detected in the posterior segment of the eye.

Due to the decrease in the transparency of the media, a surgical intervention was performed on the right eye - vitrectomy with the introduction of perfluorane and endolasercoagulation, followed by gas tamponade.

In the period between surgical operations on the left eye, a complex of laser interventions was performed according to the claimed method. The first step was laser retinal coagulation by argon laser radiation. The dimensions of the exposure spot in the focal plane of 300-500 microns, the radiation power of 200-300 mW. Laser coagulation was performed along the edge of the detachment within the intact retina until a closed coagulation loop was obtained.

The subsequent retinotomy of the tip of the “tongue” of the valve rupture was performed on a Nd: YAG laser with an energy of 3-8 mJ per pulse with peripheral sclerocompression and the use of a Goldman contact lens. The elimination of the traction effect was achieved by dosed stepwise fragmentation, the retinal “valve” deviated to the plane of the retina, the cut off portion of the retinal tissue under the influence of traction moved to the middle sections of the vitreous.

The third stage, 2 days after retinotomy, was performed transscleral infrared diode retinopexy. The exposure was carried out using radiation with a wavelength of 810 nm through a fiber with a DioPexy tip (OcuLight) at a power of 1000-1200 mW, exposure time 2.5 sec, under visual biomicroscopic control until the retina was slightly pale in the affected area. During the control examination after 2 weeks, the localized coagulation zone of rupture with local retinal detachment was transformed into a chorioretinal "adhesion" with pigmentation; no tractional influence on the “stump” of the “tongue” of the retinal valve was visually and by β-scan revealed, further progression of the gap was not determined. Visual acuity, level of intraocular pressure and field of view without dynamics.

Claims (4)

1. A method of treating peripheral retinal ruptures complicated by vitreous traction and subclinical retinal detachment by laser irradiation, characterized in that they perform laser irradiation with an argon or diode laser within the intact retina until a closed coagulation loop is obtained, followed by exposure to the retina with an Nd: YAG laser by stage-by-stage fragmentation of the “tongue” of the retinal valve, starting from the top of the gap until there is no movement of the cut-off tissue into the vitreous body and angle changes deviations of the "tongue" of the retinal valve to the plane of the retina, then after 2-3 days in the presence of detachment of the retina, infrared transscleral diode laser retinopexy is performed under visual biomicroscopic control. 2. The method according to claim 1, characterized in that the laser irradiation with an argon or diode laser is carried out at a wavelength of 485-530 nm, a radiation power of 200-300 mW, a spot size in the focal plane of 300-500 microns. 3. The method according to claim 1, characterized in that the power of the Nd: YAG laser is 3-8 mJ. 4. The method according to claim 1, characterized in that the infrared transscleral diode laser retinopexy is carried out at a wavelength of 810 nm, an exposure power of 800-1200 mW, exposure exposures of up to 3.5 s.