RU2688998C1 - Method for preoperative calculation and modification of intraocular lens by laser ablation - Google Patents

Abstract

FIELD: medicine.SUBSTANCE: invention relates to methods for preoperative calculation and modification of an intraocular lens by laser ablation. True refraction of the eye is determined in the patient according to refracto- and keratometry data. It involves keratotopography, aberrometry, calculating a spherical intraocular lens (IOL) from hydrophobic acrylic or polymethylmethacrylate (PMMA) according to known formulas for cataract surgery. To optical power of the calculated lens is added from 0.5 to 4 dioptres. Visually perceptible radial notch on the front surface of the upper part of the lens is superimposed by the cutting tool. Front surface of the lens with a center located along the visual axis of the eye is ablated with an excimer laser with wavelength of 193 nm. For distance vision is exposed in circular zone with diameter of 3–4.5 mm. For near vision, the exposure is performed in a circular zone with an inner diameter of 3–4.5 mm and an outer diameter of 4.5–6.5 mm. Diameter of circular zone coincides with internal diameter of annular zone.EFFECT: enlarging indications for performing the operation, obtaining high clinical and functional results, reducing frequency and value of inaccuracies in correcting deficiencies of eye refraction, such as myopia, hypermetropia and astigmatism, correction of presbyopia.1 cl, 1 dwg

Description

The invention relates to medicine, namely to ophthalmology, and can be used for cataract phacoemulsification in the correction of all types of refractive errors and presbyopia.

The invention relates to multifocal ophthalmic lenses, and more specifically to toric (astigmatic) multifocal intraocular lenses (TMIOL), which can provide a smooth change in the power of the lens from the center to its periphery, correct myopia, hyperopia, as well as astigmatism.

Industrially manufactured intraocular lenses of TMIOL are usually implanted into the eyes of patients during cataract surgeries to replace the natural native lens. In some industrial-scale IOLs, a multifocal structure is used, in which there are two or three foci for different distances. In other words, such IOLs provide the patient with a certain degree of accommodation (sometimes referred to as “pseudo-accommodation”), which is absent in conventional single-focus IOLs. The separation of the total light beam between the long-focus and short-focus refractive forces can be adjusted by modifying the heights of the steps of the diffraction structure and by using the central refraction zone, which directs the light exclusively into one focus. An increase in the proportion of the light beam to one focus as a whole causes a decrease in its portion to another focus, which reduces the image contrast for this focus.

The disadvantages of TMIOL is the impossibility of adjusting the size of the optical zones of the lens to the pupil size of a particular patient. It is also impossible to place the optical center of the lens exactly along the visual axis of the eye, since almost all existing industrially produced TMIOLs have symmetrical fixation elements on the sides of the lens that are needed to center the lens along the anatomical axis of the eye.

But the anatomical axis often does not coincide with the visual, which causes inaccuracies in the correction of the toric component of refraction.

The authors do not know how to modify intraocular lenses using an excimer laser.

The task of the method is the modification of industrially produced models of monofocal spherical IOLs in TMIOL using an excimer laser for further effective optical correction of the optical disturbances occurring in the eye that appear in the patient due to the removal of the native lens during cataract phacoemulsification.

The technical result of the method is the expansion of indications for performing the operation, obtaining high clinical and functional results, reducing the frequency and magnitude of inaccuracies in correcting eye refraction defects such as myopia, hyperopia and astigmatism, as well as presbyopia correction.

The technical result is achieved by the fact that the IOL before the operation is modified with an excimer laser with a wavelength of 193 nm, turning it into TMIOL. The modification is carried out by applying a notch on the upper part of the front surface of the lens on the first stage, on the side, on which side the subsequent impact of the excimer laser will occur. This is done to properly position the lens in the patient's eye during a subsequent operation. At the second stage, evaporation (ablation) of a part of the front surface of the lens (on which a notch was applied) is produced according to a pre-calculated profile (Fig. 1). It is calculated using data from keratotopography, aberrometry, autorefractometry, keratometry, spectacle correction and optical biometry of the eyes of a particular patient, as well as lens passport data (lens diameter, type of material from which it was made, A-constant).

Between the set of essential features and achievable technical result there is a causal relationship.

The lens ablation takes into account the pupil diameter in photopic (day) and scotophase (night) illumination conditions, the center of the ablation zone is located in the center of the visual axis, which is determined according to keratotopography and aberrometry, which allows to achieve the correct distribution of the working part of the optical zone of the lens in the specific eye the patient. These data are taken into account during ablation and can improve the quality of vision.

The invention is illustrated in FIG. 1, which shows a general view of a lens with a notch on it and a zone of excimer laser ablation. Position 1 denotes a radial notch, 2 - annular zone for near vision, 3 - central zone for far vision.

The method is as follows.

The patient determines the true refraction of the eye according to refractive and keratometry. Then, a spherical IOL from hydrophobic acrylic or polymethyl methacrylate (PMMA) is calculated according to known formulas for cataract surgery, using data from eye biometry. From 0.5 to 4 diopters are added to the optical power of the calculated lens, while 0.5-2 diopters are added when there is one cylindrical component without a sphere, and if there is both a spherical and cylindrical at the same time if there is one spherical component without a cylinder components, then add 2.5-4 diopters.

Cutting tool superficially applied visually viewed, 1-2 mm long, radial notch on the upper part of the lens, on the front of its surface, on which further impact of the excimer laser will occur (Fig. 1). Based on the calculated algorithm, based on keratotopography, aberrometry, refracto and keratometry data, the lens is ablated with a center located along the visual axis of the eye with an excimer laser with a wavelength of 193 nm. Both circular and annular zones are formed on the lens, while for the distant view, the impact is produced in a circular zone with a diameter of 3-4.5 mm (Fig. 2), and for near vision, the impact is produced in an annular zone with an internal diameter of 3-4.5 mm and an outer diameter of 4.5-6.5 mm. The diameter of the circular zone coincides with the inner diameter of the annular zone (Fig. 3). As a result, the patient receives simultaneously sight at two distances: at a distance, at the expense of a circular zone, and near at the expense of a circular one. The depth of exposure depends on the pre-calculated necessary lens diopter for a particular patient.

After ablation, the lens is mechanically cleaned from the impurities that appear as a result of ablation, after which it is ready for implantation into the patient's eye.

Thus, the pre-operative calculation and modification of the intraocular lens by laser ablation performed by the proposed method allows to achieve high clinical and functional results, reduce the frequency and magnitude of inaccuracies in the correction of eye refraction defects, correct the toric component of refraction, and level presbyopia phenomena.

Example 1. Patient B., 62 years old, was treated with a diagnosis of Age-related cataract OD. Visual acuity of the right eye = 0.1.

02/08/18 2 days before the operation the patient underwent diagnostic examinations: refracto-and keratometry, eye biometry, keratotopography, aberrometry. According to these data, a lens made of hydrophobic acrylic was calculated. Astigmatism was not detected in the patient, so 3 diopters were added to the calculated lens power. On the lens, in its upper part, a radial notch with a length of 2 mm was visually scanned with a blade. The ablation parameters were calculated and produced with an excimer laser with a wavelength of 193 nm with a circular zone for distance vision with a diameter of 3 mm and an annular zone for vision near the internal diameter of 3 mm and an external diameter of 4.5 mm on the side on which the notch is located. The patient underwent cataract phacoemulsification with implantation of a pre-calculated and modified intraocular lens by the claimed method. The postoperative period was uneventful. The patient was discharged 2 days after surgery. Visual acuity of the right eye 0.9.

Example 2. Patient D., 67 years old, was treated with a diagnosis of Age-related cataract OD. Visual acuity of the right eye = 0,2.

03/02/18 the day before the operation, the patient underwent diagnostic examinations: refractive and keratometry, biometrics of the eye, keratotopography, aberrometry. According to these data, a lens made of hydrophobic acrylic was calculated. The patient was diagnosed with reverse astigmatism of 1.5 diopters, and 2.5 diopters were added to the calculated lens strength. On the lens with a blade put visually visible radial notch with a length of 1 mm. Calculated the ablation parameters and produced it with an excimer laser with a wavelength of 193 nm with a circular zone for distance vision with a diameter of 4.5 mm and an annular zone for vision near the inner diameter of 4.5 mm and an outer diameter of 6.5 mm on the side on which the notch is located. The patient underwent cataract phacoemulsification with implantation of a pre-calculated and modified intraocular lens by the claimed method. The postoperative period was uneventful. The patient was discharged 2 days after surgery. Visual acuity of the right eye 1.0, astigmatism after surgery was not identified.

Claims (1)

The method of preoperative calculation and modification of the intraocular lens by laser ablation, which consists in the fact that the patient determines the true refraction of the eye according to refracto- and keratometry, conduct keratotopography, aberrometry, then calculate the spherical intraocular lens (IOL) from hydrophobic acryl or polymethyl methacrylate (Polymethyl methacrylate). known formulas for cataract surgery, add 0.5 to 4 diopters to the optical power of the calculated lens; With a cutting tool, a radial incision is visually observed on the front surface of the upper part of the lens, the front surface of the lens is ablated with a center located along the visual axis of the eye with an excimer laser with a wavelength of 193 nm. 4.5 mm, and for near vision, the impact is produced in an annular zone with an inner diameter of 3-4.5 mm and an outer diameter of 4.5-6.5 mm, while the diameter of the circular zone coincides with the inner diameter of the rings oh zone.

Images