RU2695567C1 - Method for determining angle of rotation of toric intraocular lens - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention refers to medicine, and more specifically to ophthalmology, and can be used for determining the angle of rotation of a toric intraocular lens in a capsular sac. Disclosed is a method involving determining the rotation angle of a toric intraocular lens by photographic fixation using computer programs. Algorithm of examining patients with implanted toric intraocular lenses is followed by a step-by-step study of the axial position of the toric intraocular lens after certain lens interval replacement: on the following postoperative day, 1 week, 1 month, 3 months, 6 months, consisting in certain successive combination of the obtained first and subsequent photographs in a given sequence, allowing visual and quantitative assessment of lens rotation angle change through certain temporary postoperative intervals.

EFFECT: invention provides a visual and accurate quantitative determination of the angle of inclination of the astigmatic axis of TIOL from the actual axis of corneal astigmatism in dynamics by evaluating the rotational capacity of the lens through certain time intervals when the obtained photographs are aligned.

1 cl, 2 ex

Description

The invention relates to medicine, and more particularly to ophthalmology. The essence of the method consists in using a specific algorithm for conducting a series of sequential studies of quantitative determination of the rotation angle of a toric intraocular lens (TIOL) at various time intervals, carrying out photofixation and combining the obtained photographs by means of overlapping, and is intended to determine the dynamics of the rotation angle of TIOL in a capsule bag characterizing rotational mobility lenses at various times after the lens replacement surgery in patients with astigmatism.

Modern methods of surgical treatment of cataracts allow correction of corneal astigmatism within the framework of a single surgical intervention (Malyugin B.E. 2014). Implantation of toric IOL is an effective and predictable method that allows you to correct astigmatism of more than 1.0 diopters. The main condition for the stability of the obtained functional results is the rotational stability of the IOL in the capsule bag over time, depending on various factors (anatomical, physiological - fibrosis of the capsule bag, adhesive properties of the IOL material, the severity of the postoperative inflammatory reaction, etc.) (Ohmi S, 1994, Fedyashev G.A., 2017). At the same time, the thiol has the greatest probability of rotational mobility within 1-3 months (Hyon J. Y., 2010). According to the literature, the deviation of the cylindrical component by 10 degrees reduces visual acuity by 35%, and repeated interventions to reposition the toric IOL are performed in 0.65-9% of cases (WeinandF., 2007, Zuberbuhler B, 2008). There are numerous studies, the results of which are debatable today and are devoted to determining the influence of the capsulorexis formation method (manually or using a femtolaser) on visual and refractive results, depending on the center and stable position of the IOL in the capsule bag (Kranitz K., 2014). Various methods have been proposed that increase the rotational stability of TIOL in a capsule bag (implantation of a flat intracapsular ring with special protrusions that prevent rotation of the IOL, posterior capsuleorexis, pinching of the optical part of the lens in the formed capsulorexis, using previously specially made notches, etc.). Various types of toric markers are being actively developed and applied, designed to improve the functional results of the operation by increasing the accuracy of intraoperative marking of the axis of implantation of toric lenses. However, the undisputed leader in improving the accuracy of TIOL positioning during surgery is assistant programs with digital marking devices integrated into the microscope and combining the preoperative image of the eye with the intraoperative one. In this regard, one of the important tasks, along with obtaining objective information on the exact location of the astigmatic axis of the TIOL in the postoperative period, is the ability to determine the dynamic change in the rotational stability of the lens at various times after the operation.

A known method for determining the axial position of the thiol after implantation in a capsule bag, which consists in photographing the anterior segment of the eye and determining the degree of rotation of the toric lens formed between the straight line denoting the degree of the original axis and the axis drawn through the marks of the optical part of the thiol using computer analysis carried out using the ScreenProtractor 4.0 program 3 hours after the operation, 1 and 12 months (I. Ilyinskaya, Clinical aspects of the intraocular correction of astigmatism, Moscow, 2014).

The disadvantage of this method is a simple quantitative comparison of the obtained indicators of the angle of rotation, taken photographs taken with each individual study.

Given that the achievement and preservation of high visual results is possible only with the most accurate coincidence of the cylindrical axis of the lens and the strong axis of astigmatism, the proposed research algorithm will not only quantify the angle of deviation of the implanted TIOL from the strong axis of the eye, but also conduct a comparative analysis of the rotational ability of the lens through various time intervals, giving a visual representation of the rotational stability of the lens, allowing to identify the influence of various factors and fundamentals The time intervals during which these changes occur.

The objective of the invention is to create an algorithm for the study of patients with implanted TIOL, which allows you to visually, in dynamics, track the displacement and rotational ability of the implanted lens after the lens replacement surgery in patients with astigmatism.

The technical result achieved using this research algorithm is a clear and accurate quantitative determination of the degree of the angle of deviation of the astigmatic axis of the thiol from the actual axis of the corneal astigmatism in dynamics, by evaluating the rotational ability of the lens at certain time intervals when combining the obtained photographs.

The technical result is achieved by the fact that in the method for determining the rotation angle of a toric intraocular lens in a capsule bag, which includes determining the rotation angle of a toric intraocular lens using photofixation using computer programs, when conducting an algorithm for examining patients with implanted toric intraocular lenses after a lens replacement surgery, sequential examination of the axial position of the toric intraocular lens at various times after surgery with Strongly computer program Adobe Photoshop, consisting in combining the received first and subsequent pictures by superimposing allowing visually and quantitatively evaluate a change of the angle of rotation of the lens at various time intervals post-operative.

When determining the rotation angle of a toric intraocular lens in a capsular bag, a certain algorithm is used to conduct a series of consecutive identical studies of patients after an operation to replace the lens with implanted TIOL in patients with astigmatism, including determining the axial position of the TIOL at various times after the operation using photoshop or other computer graphics programs , which consists in combining the obtained photographs by overlaying the first study, which is the original and photographs of subsequent studies, which make it possible to visually and quantitatively evaluate the deviation (change) of the rotation angle of the TIOL at various time intervals.

The method is as follows. In conditions of maximum cycloplegia in the patient’s position, sitting under a slit lamp, they mark the horizontal meridian on the cornea, then using the photo-slit lamp, the anterior segment of the eyeball is photographed with an eye on the location of the marks of the cylindrical component of the optical part of the thiol (lines or points) indicating the orientation of the toric component lenses. Using graphic computer programs equipped with vector graphics, two straight lines are drawn, one of which corresponds to the horizontal axis and coincides with marks indicating the horizontal axis of the cornea, and the second connects opposite astigmatic marks on the optical part of the lens. The angle formed between these two lines is the angle of rotation of the thiol relative to the actual axis of corneal astigmatism. Then, at certain times after the operation (the day after the operation, after 1 week, 1 month, 3 months, etc.), a series of consecutive repeated identical studies is carried out, with the first picture taken as the original version. Then, the obtained images are compared with the initial combination using graphic computer programs (Adobe Photoshop), which allows one to visually evaluate the rotational ability of the TIOL and quantitatively characterize the change in the angle of deviation of the cylindrical component of the lens from the actual astigmatic axis of the eye in degrees, thus demonstrating the dynamics of the rotation angle lenses in comparison with the previous or initial research for a certain time period. The highest rotational mobility of TIOLL is observed in patients up to 3 months. after operation. Lack of lens rotation after 3 months. after the operation, it can be explained by the final process of fibrosing of the capsular bag and the final stabilization of visual indicators.

This method was tested in a clinic on 20 patients. The displacement of the thiol is determined with an accuracy of 0.1 °. A significant advantage of the method over the analogue is a visual demonstration of the dynamics of the rotation angle of the TIOL, which allows a comprehensive comparative analysis of the rotational ability of the TIOL in the capsule bag, including not only a quantitative measurement of the rotation angle, but also a visual determination of the comparative change in the position of the lens relative to the strong axis, relating it to the intervals time during which significant deviations occur, allowing to identify factors that have a decisive influence on the stability of PS at the moment.

The invention is illustrated by the following examples.

Example 1. Patient M., 68 years old, Ds: Artifakia of the right eye. Visual acuity of 0.7 n / a. Data of lability of the optic nerve: a slight decrease in lability of the optic nerve, perimetry is normal. PZO = 23.2 mm. History: 6 months. Uncomplicated phacoemulsification of cataract and implantation of thiol was performed back. The postoperative period was uneventful. When carrying out the developed algorithm for examining a patient the day after surgery, after 1 month, after 3 months, after 6 months, processing the obtained photographs in a graphical computer program, by overlaying a photograph taken the next day after the operation (initial) with photographs, made after 1 month, after 3 months and after 6 months, a noticeable increase in the rotation angle was revealed compared to the original after 1 month by 0.5 °, after 3 months by 1.5 ° compared to the previous one, while the same position was recorded rotaz angle TIOL and at 3 months and 6 months., consisting in matching the angle of rotation between the two images compared with the initial and pictures taken at 1 month.

Example 2. Patient N., 58 years old, Ds: Artifakia of the left eye. Myopia of a high degree. Myopic retinal dystrophy. Visual acuity of 0.4 n / a. Optical nerve lability, perimetry, and B-scan examination data are normal. PZO = 25.8. The patient is 6 months old. ago, phacoemulsification of partial complicated cataract with Thiol implantation was performed to correct moderate corneal astigmatism (-3.25 diopters). During the entire observation period (1 month, 3 months, 6 months), the patient was examined according to the developed algorithm for the study of patients with TIOL implantation. At the same time, the patient insisted on surgical treatment in view of the positive refractive prognosis after implantation of TIOL. When viewed after 1 month, the patient complained of vagueness, blurred vision. Visual acuity was 0.3-0.4 n / a. As a result of processing the obtained photographs after 1 month, combining two images taken the next day after the operation and 1 month later, by overlay using graphic programs, it was established: the difference between the TIOL angle and the strong axis was 15 °. This value exceeds the average statistical rotation of the thiol, which, according to various authors, may be 4.9 ± 2.1 °. Among the various versions of the causes of TIOL rotation, one can consider the existing connection with myopic refraction of the eye, which regards the larger size of the capsular bag as a risk factor for increased IOL rotation. Given the available indicators obtained in this situation, it is possible to consider the question of repeated surgical intervention with the aim of repositioning the IOL. After the reposition of complaints, the patient did not show complaints, visual acuity increased to 0.6 and remained stable throughout the entire observation period. Analysis of the combination of photographs obtained after reposition after 1 month, 3 months and 6 months clearly showed the coincidence of astigmatic marks on the optical part of the lens and the strong axis of the eye, characterizing the absence of rotation of the IOL.

Thus, the presented research algorithm has an advantage over other methods for determining the rotation angle, which consists not only in accurate quantitative, but also visual determination of the degree of rotation of the thiol in the capsule bag and identifying the most significant timing of the rotation of thiol, while the demonstration nature of the study, which consists in an automated approach when applying the first and subsequent shots, it allows you to control the dynamics of the angle of rotation of the lens and provides communication with time intervals, helping I establish the possible causes of rotation and making it indispensable in deciding on further tactics for managing the patient in difficult situations.

Claims (1)

A method for determining the rotation angle of a toric intraocular lens in a capsule bag, comprising determining the rotation angle of a toric intraocular lens using photographic fixation using computer programs, characterized in that during the algorithm for examining patients with implanted toric intraocular lenses after a lens replacement operation, a phased study of the axial position is carried out toric intraocular lens at specific time intervals: the day after surgery and, 1 week, 1 month, 3 months, 6 months, which consists in a certain sequential combination of the obtained first and subsequent photographs in a given sequence, which allows you to visually and quantitatively assess the change in the angle of rotation of the lens at certain time postoperative intervals.