RU2441631C2 - Method for gradual stepwise laser treatment of retinoschisis - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention is referred to the area of medicine, namely to the area of ophthalmology, and can be used for retinoschisis treatment. For this purpose coagulating exposure to laser radiation is performed. The method uses the radiation of diode laser with the wavelength 0.83 mcm, radiation power from 350 to 850 mW, exposure 0.2-0.3 s for each coagulate, spot diameter 150-200 mcm. First the limiting coagulation of macular area is performed. Then the coagulates are placed from the center of retina to periphery on the retinoschisis surface and along the vascular archs to retinoschisis flattening. In the absence of visible resorption the exposure is repeated for 2-5 times with the interval 1-4 weeks. EFFECT: method provides for preservation of retina surface layers, speed up of resorption of intraretinal fluid with cyst deflation and preservation of retina function due to preservation of macular area and formation of shunts between outer retina and choroid layers.

3 ex, 1 dwg

Description

The present invention relates to ophthalmology and is intended for the treatment of cysts of the retina of the eye. Until now, the treatment of retinoschisis is a difficult task, and its solution remains the subject of lively discussion and contradictions of ophthalmologists around the world (E.S. Libman. Retinal cysts and their treatment. 1971. - P.78-83).

In addition, it is known that every year the number of patients with retinoschisis increases, and retinal cysts occur with glaucoma, vascular disorders, proliferative diabetic retinopathy, age-related degenerative changes in the retina, injuries, hereditary degenerative diseases and are often combined with myopia. Conservative methods of treatment for these pathological conditions are ineffective. Therefore, many ophthalmologists prefer less traumatic, but reliable laser methods of exposure to cysts of the retina (Brockhurst R.J. Photocoagulayion in Congential retinoschisis // Arch. Ophthalmol. - 1970. - Vol.84. - No. 2. - P.158-165).

It is known to use argon laser coagulation in progressive retinoschisis using Visualas 532 nm, Carl Zeiss, with a coagulate diameter of 200-300 μm, an exposure of 0.05-0.1 s, and a power of 90-200 μV. Laser coagulation is recommended as a “laser circulation” along the edge of the retinoschisis along the entire circumference in two rows in a checkerboard pattern, and with the hemorrhagic form of the cyst, combine laser-coagulation with coagulation between the newly formed vessels (Mosin I.M. X-linked juvenile retinoschisis: Literature review / / Bulletin of Ophthalmology. - 2000. - T. 116. - No. 4. - S.41-45).

There is a method of treating degenerative retinoschisis using argonlasercoagulation for a delimiting barrier procedure on an NM device, the RSDO model (USA) with a radiation power of 0.2-0.45 W, exposure 0.1-0.2 s and a spot diameter of 100 microns to obtain coagulates of 2-3 degrees of intensity, which allows to stabilize the process in 80% of cases (Potekhin V.K. et al. Argon laser coagulation in patients with retinoschisis // Abstracts of the 7th Congress of Russian Ophthalmologists. - 2000. - Part 1. - C .474-475). This method is taken as the closest analogue.

The disadvantages of the method of argon laser coagulation during retinoschisis are: a strong blinding effect of the blue-green spectrum of radiation on the patient’s eye, causing profuse lacrimation and photophobia, which is often impossible to carry out. Burns with an argon laser mainly affect the area of pigment epithelial cells and almost do not affect the choroid of the eye, while a slight increase in radiation intensity always leads to coagulation of all layers of the retina, including internal ones with corresponding consequences. Therefore, burns with green radiation appear instantly in the process of laser exposure and with a minimal overdose can lead to the appearance of epiretinal fibrosis due to damage to the inner layers of the retina. Damage to nerve fibers increases even more when exposed near the macular zone of the retina, since the yellow pigment lipofuscin intensively absorbs blue-green radiation from an argon laser. In addition, a more significant damage to the blood-ophthalmic barrier occurs as well. the risk of developing proliferative retinopathy is increased. In patients with circulatory disorders in the retinal capillary network, accompanied by fluid exudation into the layers of the retina, when using an argon laser, it is possible to obtain its resorption only in 57% with some deterioration in visual acuity (Balashevich LI Creation and study of the effectiveness of using argon and diode lasers for fundus pathology. Diss. in the form of a scientific report for the degree of Doctor of Medical Sciences. - SPb., 1996. Pages 28-37).

The objective of the invention is to improve the method of laser coagulation in the treatment of retinoschisis.

The technical result of the proposed method is to preserve the surface layers of the retina, accelerate the resorption of the intraretinal fluid with the cyst collapsing and preserving the function of the retina.

The technical result is achieved through the use of a diode laser with a wavelength of 0.83 μm, a radiation power of 350 to 850 mW, an exposure of 0.2-0.3 s for each coagulate, a spot diameter of 150-200 μm and conducting delimiting coagulation in the macular region with the application of coagulates from the center of the retina to the periphery along the surface of the retinoschisis and along the vascular arcades until the retinoschisis is flattened.

The prerequisites of this invention were the data obtained by L.I. Balashevich on the resorption of intraretinal fluid with an improvement in visual functions in the treatment of exudative maculopathy with a diode laser. The use of a near-infrared laser in the treatment of retinoschisis can be justified by its ability to coagulate pigment epithelium and choroid without any signs of changes in the vessels of the retina, because maximum energy absorption occurs in the pigment epithelium with a shift in the thermal effect towards the choroid. In addition, long-wavelength laser radiation is weakly absorbed by lipofuscin, and therefore can pass through the inner layers of the macula retina without damaging its structure (V.V. Volkov., L.I. Balashevich. On the choice of a generator for photocoagulation of the fundus. Ophthalmol. Zh. - 1978. - No. 5. P.330-333; Brancato R., Pratesi R. Applications of diode lasers ophthalmology. - 1987. - Vol.1. - No. 3 - P.129-199). In this case, it is possible that there is a closer contact of the stratified retina with the choroid through the formation of so-called laser shunts and, as a result, the resorption of the intraretinal fluid. Subsequently, this can be expressed by a complete decline in the retinoschisis leaves, and therefore, retinal function preservation.

For coagulation, you can use, for example, the domestic diode laser "Milon Lahta". The radiation parameters were selected and amounted to: wavelength - 0.83 μm, radiation power from 350 to 850 mW (depending on the degree of pigmentation of the fundus), laser exposure - 0.2-0.3 s, focal spot diameter in the focal the plane of the slit lamp is 150-200 microns. At the same time, the boundary macular region coagulation was first made, then the coagulates were applied from the center of the retina to the periphery along the surface of the retinoschisis and along the vascular arcades until the retinoschisis was flattened. The delimiting coagulation made it possible to create a barrier against the penetration of intraretinal fluid into the macular zone and, therefore, to maintain visual functions. This is possible using infrared radiation from a diode laser, in contrast to an argon laser, the radiation of which is harmful to the macular zone. In addition, the application of coagulates from the center of the retina to the periphery contributes to the conservation of the macular region. In this case, the resorption of the intraretinal fluid will occur gradually, which excludes its flow into the macular region of the retina. The application of coagulates along the vascular arcades and blood vessels prevents the penetration of fluid into the layers of the retina, and the application of coagulates on the surface of the retinoschisis provides the formation of shunts between the outer layers of the retina and the choroid, facilitating the resorption of the intraretinal fluid with subsequent formation of the chorioretinal adhesion and, accordingly, the retraction of the retinoschisis.

The method is as follows.

Example 1. Patient K. applied for a routine examination with high myopia. A detailed ophthalmoscopic examination of the retina revealed a peripheral progressive retinoschisis, occupying the lower part of the fundus. On the same day, diode laser coagulation of the retina was performed, the radiation power of which was 300-500 mW, the exposure was 0.2-0.3 s for each coagulate, the spot diameter was 150-200 microns. First, a delimiting coagulation of the macular region was performed, then the coagulates were applied from the center of the retina to the periphery along the surface of the retinoschisis and along the vascular arcades until the retinoschisis was flattened. After 3 weeks during examination, a marked flattening of the height of the retinoschisis, good pigmentation of most of the laser coagulation were noted. After 6 months, an ophthalmoscopy revealed complete resorption of the intraretinal fluid, preservation of visual functions at the preoperative level.

Example 2. Patient S. consulted for progressive stage 2 retinoschisis. During the examination, a widespread retinoschisis was found, occupying the lower and inner halves of the fundus and reaching the central part of the retina. The patient was prescribed instillations of mydriatics 4 times a day, take Troxevasin 2 capsules 3 times a day inside and observe bed rest for 2 days. After that, a laser coagulation session was conducted with a radiation power of 500 to 800 mW, an exposure of 0.2-0.3 s for each coagulate, and a spot diameter of 150-200 microns. First, a delimiting coagulation of the macular region was performed, then the coagulates were applied from the center of the retina to the periphery along the surface of the retinoschisis and along the vascular arcades until the retinoschisis was flattened. However, no visible resorption was observed after 1 week. Therefore, repeated exposure. Then we spent another 2 sessions at intervals of 7 days. As a result, a complete blockade of a limited section of the retinoschisis in the lower inner part of the retina was obtained with several rows of pigmented laser coagulates. In this case, managed to maintain high visual acuity. In the observation period of up to 2 years, there was no progression of the process and changes in visual acuity.

Example 3. Patient P. was diagnosed with advanced stage 3 retinoschisis. Examination revealed a common retinoschisis, which occupies the entire outer and lower halves of the fundus, reaching the macular region and has a higher retention in the lower and outer quadrants of the retina. In the meridian of 6.30-7.0 hours, the presence of two hole breaks in the inner sheet of the retina was determined. After 5 days of preparation, the first session of phased translational laser coagulation was performed. The radiation power in this case was 500–850 mW, the exposure was 0.2–0.3 s for each coagulate, and the spot diameter was 150–200 μm. First, a delimiting coagulation of the macular region was performed, then the coagulates were applied from the center of the retina to the periphery along the surface of the retinoschisis and along the vascular arcades until the retinoschisis was flattened. Thus, three sessions were conducted with an interval of 4 weeks. At the same time, it was possible to move the cyst away from the central zone of the retina and create a reliable barrier of four rows of pigmented laser coagulates. Visual acuity before treatment was 0.5-0.6 with myopic correction, and after treatment 1.0 with the same correction. With a follow-up period of 1 year, stabilization of the process is maintained.

Thus, the proposed method of laser treatment of retinoschisis provides a complete resorption of intraretinal fluid, the preservation of the macular region and, accordingly, visual functions. The method can essentially be called phased translational laser coagulation of retinoschisis.

Claims (1)

A method of laser treatment of retinoschisis, including the coagulating effect of laser radiation, characterized in that they use the radiation of a diode laser with a wavelength of 0.83 μm, a radiation power of 350 to 850 mW, an exposure of 0.2-0.3 s for each coagulate, spot diameter 150-200 microns, while first producing a delimiting coagulation of the macular region, then the coagulates are applied from the center of the retina to the periphery along the surface of the retinoschisis and along the vascular arcades until the retinoschisis is flattened, in the absence of visible resorption repeat 2-5 times with an interval of 1-4 weeks.