RU2801958C1 - Method of calculating the refractive effect during intrastromal ring implantation - Google Patents

Abstract

FIELD: medicine, ophthalmology.

SUBSTANCE: height of the implanted intrastromal ring is selected to correct high myopia. The height of the implanted ring is determined by selection with parameters from 200 to 400 µm in increments of 20 µm. The refractive effect is predicted on the basis of regression analysis according to the formula R₁+0.005×h+0.001×C, taking into account the height of the implanted ring h, the depth of its occurrence in the stroma C and the initial radius of curvature of the cornea R₁.

EFFECT: increasing the predictability of the refractive effect and achieve maximum clinical and functional results.

1 cl, 2 ex

Description

The invention relates to medicine, and more specifically to ophthalmology, and can be used to calculate the refractive effect in the correction of myopic refraction, including induced in combination with regular and irregular corneal astigmatism by intrastromal ring implantation.

Among the methods of surgical correction of high myopia without or in combination with astigmatism, refractive interventions on the cornea are primarily preferred, namely, LASIK technology (laser-assisted in situ keratomileusis) in its various modifications (Mushkova I.A., 2013; Doga A.V., 2016; Moussa S., 2019) and intraocular methods such as implantation of a negative phakic intraocular lens (PIOL) and replacement of a transparent or clouded lens (Fedorov S.N., 1969; Zuev V.K., 1984; Tumanyan E.R., 1987; Zuev V.K. 1995; Balashevich L.I., Radchenko A.G., 1998; Agafonova V.V., 2000; Balashevich L.I., 2002; Sorokoletov G.V. , Zuev V.K., Tumanyan E.R. et al., 2015, Rattan S.A, 2017). At the same time, it is well known that corneal refractive surgery has a limited margin of acceptable correction, depending on the initial parameters of the cornea and the degree of myopia, not all patients meet the generally accepted standards and selection criteria for PIOL implantation, and not all patients agree to abdominal surgery due to the risk possible complications (Torun N., Bertelmann E., Klamann M.K., Maier A.K., 2013; Balashevich L.I., 2002; Řeháková T., 2018; Sucu M.E., 2021). In such cases, another alternative method for correcting myopic ametropia is used - intrastromal ring implantation (Daxer A, 2007; Rattan S.A., 2017; Pashtaev N.P., Pozdeeva N.A., M.V. Sinitsyn, 2013). Currently, intrastromal ring implantation is also successfully used to correct induced ametropia, including after corneal transplantation (Sinitsyn M.V., 2020).

A known method for correcting moderate and high myopia by implantation of the MyoRing ring, which consists in calculating the refractive effect in the correction of moderate and high myopia in combination with a thin cornea by implanting the MyoRing ring into the intrastromal pocket formed using FSL at a depth of 80-87% of the minimum corneal thickness based on determining the parameters of the implantable MyoRing ring (diameter from 5.0 to 7.0 mm and height from 200.0 to 400.0 µm with a step of 20 µm) depending on the spherical component of refraction (Pat. 2715279 RF dated 08.05 2019. A method for correcting moderate and high myopia in combination with a thin cornea / Pashtaev N.P., Pozdeeva N.A., Sinitsyn M.V., Terentyeva A.E.).

This method does not take into account the radius of curvature of the cornea and the depth of implantation of the ring to calculate the refractive effect, which can lead to hypo- or hypercorrection.

The objective of the invention is to develop a formula for calculating the refractive effect when correcting myopic ametropia by implanting an intrastromal ring based on mathematical analysis by selecting the relationship between the radius of curvature of the cornea and the height of the ring, the radius of curvature of the cornea and the depth of implantation of the ring.

The technical result of the invention is to increase the predictability of the refractive effect and achieve maximum clinical and functional results.

The technical result is achieved by the fact that in the method for calculating the refractive effect during implantation of the intrastromal ring, including determining the height of the implanted ring by selecting parameters from 200 to 400 μm in increments of 20 μm, the refractive effect is predicted based on regression analysis according to the formula R ₁ +0.005×h +0.001×C, taking into account the height of the implanted ring h, the depth of its occurrence in the stroma C and the initial radius of curvature of the cornea R ₁ .

In the method for calculating the refractive effect in the correction of myopic ametropia during implantation of an intrastromal ring, a mathematical regression analysis is carried out with the study of a linear and quadratic model to identify the relationship between the radius of curvature of the cornea and the height of the ring, the radius of curvature of the cornea and the depth of implantation of the ring.

In the method for calculating the refractive effect during intrastromal ring implantation, mathematical calculations are carried out using regression analysis in the statistical mathematical package SPSS-28.0.

The method of treatment according to the invention is carried out as follows. In the course of the work, the following designations were introduced: ΔR - change in the radius of curvature of the cornea, mm; R ₁ - radius of curvature of the cornea before surgery, mm; R ₂ - radius of curvature of the cornea after surgery, mm; h is the height of the ring, microns; C - depth of implantation of the ring, microns. We looked for a relationship equation between ΔR and h, as well as a relationship equation between ΔR and C. However, paired regressions and multiple regressions were built. The conducted regression analysis showed that it is advisable to dwell on a linear or quadratic relationship, which have the form: y=a+bx or y=a+bx+cx ² . First, we considered a model of the relationship between the change in the curvature of the cornea from the height of the ring and built regression equations. From the summary for the linear model, it was obtained that the R-squared (multiple determination coefficient, which indicates the quality of predictability) is 0.861. This means that the height of the ring (h) explains 86.1% of the variability in the radius of curvature of the cornea (ΔR), which indicates a fairly good quality of the linear model. From the summary for the quadratic model, R-squared is 0.862. This means that the height of the ring explains 86.2% of the variability in the radius of curvature of the cornea, which indicates a fairly good quality of the quadratic model.

Linear Model Summary

Summary for Quadratic Model

Further, a model of the relationship between the change in the curvature of the cornea and the depth of implantation of the ring was considered. From the summary for the linear and quadratic models, it can be seen that the quality of the quadratic model is identical to the quality of the linear model, and the depth of implantation of the ring explains 87.7% of the variability in corneal curvature.

Linear Model Summary

Summary for Quadratic Model

As a result of the calculations, the regression coefficients for the height of the ring and the depth of implantation of the ring were identified.

Based on the calculations, the multiple regression model had the following form:

The calculation of the refractive effect is carried out by entering into the formula the initial radius of curvature of the cornea, the depth of implantation of the ring and the height of the ring with the selection of parameters from 200 to 400 µm (in 20 µm increments) to obtain the highest possible refractive result in each specific case.

After the calculated radius of curvature of the cornea is converted into keratometric diopters according to the following formula:

D - optical power of the cornea

KI - keratometric index - the ratio between the anterior and posterior surfaces of the cornea = 1.3375.

Thus, the derived formula makes it possible to obtain a high predictability of the refractive effect in patients for the correction of myopic refraction by implanting an intrastromal ring. The use of the formula contributes to a significant increase in functional results during implantation of the ring by selecting the required height to correct a certain amount of myopic ametropia. The use of the proposed method for calculating the refractive effect contributes to the social and professional rehabilitation of patients.

This method was tested on 10 patients. The present invention is illustrated by the following examples.

Example 1. Patient V., 27 years old. Diagnosis: OD - High myopia, complex myopic astigmatism. Mild amblyopia. Visual acuity: OD=0.02 sph -10.5, cyl -1.0 ax 97°=0.6. Refractometry: OD sph -11.5 cyl -1.5 ax 95°. Mean value of keratometry (Ksr): OD 45.25 diopters. Radius of curvature of the cornea: OD 7.46 mm. The minimum thickness of the cornea in the center according to the tachymetric map on OCT Visante was OD: 493 µm. According to computed keratotopography on Tomey-4 and analysis of elevation maps on the Pentacam apparatus, there were no data for keratectasia. According to the formula for calculating the refractive effect, it was found that it is necessary to implant a ring with a height of 300 μm.

The patient underwent intrastromal implantation of the MyoRing ring using an optimized technology. The operation was performed under local installation anesthesia (inocaine 0.4%) in 2 stages. At the first stage, a corneal pocket with a diameter of 8.0 mm was formed at a depth of 80% (394 μm) of the initial thickness of the cornea with the aim of possible additional correction in the future, using a FemtoVisum 1 MHz femtosecond laser (Troitsk, Russia). In stage II, a MyoRing ring with an inner diameter of 5.0 mm, a width of 0.5 mm and a height of 300 μm was inserted into the formed pocket with special tweezers.

At discharge visual acuity without correction: OD was 0.4 n/K. Refractometry: OD sph -0.5 D cyl -0.25D ax 96°. Ksr 35.5 diopters. After 3 months visual acuity without correction: OD 0.5. Refractometry: OD sph +0.25 D cyl -0.5 D ax 124°. Ksr OD 35.0 diopters.

Example 2. Patient D., aged 28. Diagnosis: OS - High myopia, complex myopic astigmatism. Mild amblyopia. Visual acuity: OS=0.04 sph -7.5, cyl -1.0 ax 24°=0.7. Refractometry: OS sph -7.5 cyl -1.0 ax 28°. Mean value of keratometry (Ksr): OS 42.25 diopters. Radius of curvature of the cornea: OS 7.99 mm. The minimum thickness of the cornea in the center according to the pachymetric map on OCT Visante: OS 480 µm. According to computed keratotopography on Tomey-4 and analysis of elevation maps on the Pentacam apparatus, there were no data for keratectasia. According to the formula for calculating the refractive effect, it was found that it is necessary to implant a ring with a height of 280 microns.

The patient underwent intrastromal implantation of the MyoRing ring using an optimized technology. The operation was performed under local installation anesthesia (inocaine 0.4%) in 2 stages. At the first stage, a corneal pocket with a diameter of 8.0 mm was formed at a depth of 80% (384 μm) of the initial thickness of the cornea, if further correction was necessary, using a FemtoVisum 1 MHz femtosecond laser (Troitsk, Russia). In stage II, a MyoRing ring with an inner diameter of 5.0 mm, a width of 0.5 mm and a height of 280 μm was inserted into the formed pocket with special tweezers.

At discharge visual acuity without correction: OS 0.5 n/a. Refractometry: OS sph -0.25 D cyl -0.5D ax 35°. Kcp 34.5 diopters. After 3 months visual acuity: OS 0.6 sph -0.5D cyl -0.5D ax 36°=0.7. Refractometry: OS sph -0.5 D cyl -0.5 D ax 25°. Kcp OS 35.0 diopters.

Claims (1)

A method for selecting the height of an implantable intrastromal ring for the correction of high myopia, including determining the height of the implanted ring by selecting parameters from 200 to 400 μm in increments of 20 μm, characterized in that the refractive effect is predicted based on regression analysis according to the formula R ₁ +0.005×h +0.001×C, taking into account the height of the implanted ring h, the depth of its occurrence in the stroma C and the initial radius of curvature of the cornea R ₁ .