RU2379012C1 - Method of surgical correction of myopic astigmatism - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention relates to field of ophthalmology and can be used for surgical correction of myopic astigmatism. Cornea is influenced by layer-by-layer ablation with pulse irradiation of non-scanning excimer laser with Gauss radial space distribution of energy density in transverse section of ray. Wavelength is 193-250 nm, diametre of laser impact zone 5-9 mm, pulse duration 15-30 ns, pulse recurrence rate 5-15 Hz. Influence is performed by successive reduction of parametre of mean square deviation of energy density distribution in each of next pulse series is within the interval from 2.7 to 1.8 mm. Value of amplitude of energy density in centre of pulse symmetry is within the interval from 100 mJ/sq cm to 175 mJ/sq cm and remains constant during all time of pulse series carrying out. Each pulse series forms concave with respect to initial cornea surface ellipsoidal surfaces located on one axis. Zone of exposure is symmetrical relative to optic centre of cornea symmetry. Position of weak axis of astigmatism is determined and large axis of formed ellipsoidal surfaces is superimposed with it.

EFFECT: method allows to reduce eye tissue trauma with simultaneous reduction of post-operation complications and volume of ablated eye tissues.

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Description

The invention relates to the field of ophthalmic surgery.

A known method of surgical correction of myopic astigmatism using excimer radiation from a non-scanning excimer laser with a wavelength of λ = 193 nm. Surgical action on the cornea is carried out due to the parameters of the amplitude (A) of the energy density in the center of symmetry of the pulse, the value of "sigma", the diameter of the ablation zone, and the number of pulses. The parameter “sigma” (σ) means the parameter of the standard deviation of the Gaussian radial distribution of the energy density in the cross section of the beam (see D. Hudson. Statistics for physicists. 2nd supplemented edition. Translated from English by M., Mir, 1970, pg. 30-32). When correcting myopic astigmatism, a spatial elliptical (and not round, as in the correction of myopia) geometric profile of the beam cross section is formed, while the degree of ellipticity corresponds to the magnitude of the corrected astigmatism (see Kachalina GF Surgical technology of transepithelial photorefractive keratectomy in case of myopia with excimer laser installation Profile-500. "Abstract of Ph.D. thesis. M., 2000, p. 10, as well as A. D. Semenov, A. Doga, G. F. Kachalina and others. Photoastigmatic refractive ke ratectomy on the Profile-500 installation in the correction of complex myopic astigmatism. Ophthalmosurgery, No. 4, 2000, p. 4). In this case, all the indicated parameters (except for the number of pulses) are set in the form of certain quantities and remain unchanged during the operation. Each of the parameters of the effect of excimer laser radiation on the cornea contributes to the result: “sigma” determines the geometry of the spatial effect, the amplitude of the energy density - the intensity of the exposure and partially the geometry, the number of pulses - the final refraction. The main refractive effect is determined by the number of pulses along the stroma of the cornea (see Kachalina GF Surgical technology of transepithelial photorefractive keratectomy in case of myopia on the Profile-500 excimer laser apparatus. Abstract of candidate dissertation. M., 2000, pp. 9-14) .

However, this method has significant drawbacks: a sufficient traumatic effect on the tissues of the eye due to the large amount of energy received during the implementation of laser exposure. In addition, in some cases, there is the occurrence of postoperative complications in the form of corneal opacities.

Technical task: to reduce trauma to the tissues of the eye while reducing postoperative complications and the volume of removed eye tissue.

The technical problem is solved in that in the method of surgical correction of myopic astigmatism, which consists in exposing the cornea by layer-by-layer ablation by pulsed radiation of a non-scanning excimer laser with a Gaussian radial spatial distribution of energy density in the beam cross section, the effect is produced by sequentially decreasing the standard deviation of the energy density distribution in each of the subsequent series of pulses in the range from 2.7 mm to 1.8 mm, while the value of the amplitude of the energy density at the center of symmetry of the pulse lies in the range from 100 mJ / cm2 to 175 mJ / cm2 and remains constant throughout the series of pulses, and within each series of pulses the value of the standard deviation of the energy density distribution is constant, at In this case, each series of pulses forms ellipsoidal surfaces concave with respect to the initial surface of the cornea, facing concavity towards the front surface of the cornea, and the impact zone is symmetrical with respect to Tel'nykh optical center of symmetry of the cornea;

initially determine the position of the weak axis of astigmatism and combine with it the large axis of the formed ellipsoidal surfaces;

then form the first concave ellipsoidal surface, while the ratio of the length of the major axis of the concave ellipsoidal surface to the diameter of the cornea lies in the range 0.6 to 0.8;

then form a second concave ellipsoidal surface, and the ratio of the length of the major axis of the second ellipsoidal surface to the length of the major axis of the first ellipsoidal surface lies in the range from 0.8 to 0.95;

then they form a third concave ellipsoidal surface, the ratio of the length of the major axis of the third ellipsoidal surface to the length of the major axis of the second ellipsoidal surface lies in the range from 0.8 to 0.95, and the surface of the cornea is exposed to radiation from an excimer laser with a wavelength of 193-250 nm, with a diameter zones of laser exposure from 5 to 9 mm, pulse duration 15-30 ns, pulse repetition rate from 5 to 15 Hz.

The set of essential distinguishing features proposed by the author is necessary and sufficient for the unique achievement of the task.

The author has done a lot of work, allowing to determine the intervals of the main parameters. The value of the standard deviation of the energy density distribution in each of the subsequent series of pulses lies in the range from 2.7 mm to 1.8 mm and it cannot be less than 1.8 mm, because the diameter of the formed optical zone becomes less than the diameter of the central optical zone, and cannot be more than 2.7 mm, because a larger diameter of the optical zone is impractical to achieve the claimed technical problem.

The value of the amplitude of the energy density in the center of symmetry of the pulse remains constant throughout the series of pulses and lies in the range from 100 to 175 mJ / cm2. It cannot be less than 100 mJ / sq. Cm, since this value is an effective threshold for ablation, and more than 175 mJ / sq. Cm, since non-linearities of the ablation process arise, which make it difficult to achieve the stated technical problem.

The method is illustrated by drawings.

Figure 1 is a sequence of decreasing the standard deviation of the distribution of the energy density of the laser beam ("sigma") along the weak axis of astigmatism. The abscissa shows the distance from the center of the cornea in millimeters. The ordinate axis is the energy density of the laser beam in mJ / cm2.

Figure 2 is a top view of the impact zone. The coordinate axes show the distance in millimeters from the optical center of the cornea. For the weak axis of astigmatism, the position of the abscissa axis is taken. In case the major axis of astigmatism is at an angle, the axes of all elliptical surfaces are also located at the same angle.

Figure 3 is a frontal section of the resulting surface. The horizontal axis represents the distance in millimeters from the optical center of the cornea.

The method is as follows.

A method of surgical correction of myopic astigmatism consists in acting on the cornea by layerwise ablation by pulsed radiation of a non-scanning excimer laser with a radial spatial Gaussian distribution of the energy density in the beam cross section.

The impact is produced by sequentially decreasing the standard deviation of the energy density distribution in each of the subsequent series of pulses in the range of 2.7 mm to 1.8 mm. The parameter "sigma" - the standard deviation of the energy density distribution - in this invention is (compared with the prototype) variable, which greatly increases the efficiency of the proposed method.

In Fig. 1, 1 denotes the initial shape of the energy density distribution curve, 2 denotes an intermediate form, and 3 denotes the final shape of the energy density distribution curve. During exposure, the shape of the energy density distribution curve becomes more pointed while maintaining a constant amplitude. The decrease in the "sigma" from the first series of pulses to the next is performed stepwise. Moreover, within each series of pulses the value of the "sigma" value is constant.

The value of the amplitude of the energy density in the center of symmetry of the pulse lies in the range from 100 mJ / cm2 to 175 mJ / cm2 and remains constant throughout the series of pulses. Each series of pulses forms concave ellipsoidal surfaces facing concavity towards the front surface of the cornea. The exposure zone is symmetrical with respect to the optical center of symmetry of the cornea.

The formation of surfaces under the influence of laser radiation is presented in figure 2 and figure 3. 3, reference numeral 4 denotes the initial surface of the cornea.

The optical axis of the laser radiation is combined with the optical center of the cornea. The position of the weak axis of astigmatism is determined and the large axis of the formed ellipsoidal surfaces is combined with it.

First form the first concave ellipsoidal surface (Figure 2, 1, Figure 3, 1), while the ratio of the length of the major axis of the concave ellipsoidal surface to the diameter of the cornea lies in the range 0.6 to 0.8.

Next, a second concave ellipsoidal surface is formed (FIG. 2, 2, FIG. 3, 2), the ratio of the length of the major axis of the second ellipsoidal surface to the length of the major axis of the first ellipsoidal surface lies in the range from 0.8 to 0.95.

Next, a third concave ellipsoidal surface is formed (FIG. 2, 3, FIG. 3, 3), while the ratio of the length of the major axis of the third ellipsoidal surface to the length of the major axis of the second ellipsoidal surface lies in the range from 0.8 to 0.95.

The value of the amplitude of the energy density in the center of symmetry of the pulse lies in the range from 100 mJ / cm2 to 175 mJ / cm2 and remains constant throughout the series of pulses.

The impact on the surface of the cornea is produced by radiation of an excimer laser with a wavelength of 193-250 nm, with a diameter of the laser irradiation zone from 5 to 9 mm, a pulse duration of 15-30 ns, and a pulse repetition rate of 5 to 15 Hz.

All surfaces obtained by these methods are concave with respect to the original front surface of the cornea. The degree of concavity uniquely determines the optical power of the surface. The optical power of each of the surfaces formed in accordance with the claims is constant, but varies from surface to surface, with the central segment having a minimum optical power with respect to the original surface of the cornea. The value of this value is calculated in advance before the operation to provide the patient with normal, proportional refraction in the central optical zone. The number of pulses required for the formation of each of the surfaces is constant, but different for each of them. The sequential decrease in the standard deviation of the energy density distribution in each of the subsequent series of pulses at a constant value of the amplitude of the energy density in the center of symmetry of the pulse throughout the series of pulses allows, in combination with the other parameters indicated in the characterizing part of the claims, to unambiguously solve the claimed technical problem.

The proposed invention is characterized by the following clinical examples.

Example 1. Patient B., 23 years old.

Condition before surgery:

Visual acuity in the distance: Vis OD = 0.07 Sph -5.0 D Cyl -1.75 D Ax 180 = 0.9

Vis OS = 0.07 Sph -5.0 D Cyl -1.75 D Ax 180 = 0.9

Corneal thickness: 518 microns.

Diagnosis: moderate stationary myopia, complex myopic astigmatism in both eyes.

The operation in accordance with the proposed invention.

First series of pulses Second series of pulses Third series of pulses "Sigma" (σ) along the weak axis, mm 2.53 2.40 2.20 Sigma (σ) along the strong axis, mm 2.08 1.97 1.81 Amplitude of energy density (A), mJ / sq.cm 175 175 175 The number of pulses along the stroma of the cornea 300 200 113

Condition after surgery (1 year):

Visual acuity in the distance: Vis OD = 0.9 Vis OS = 1.0

Corneal thickness: 455 microns, the cornea is transparent.

Example 2. Patient P., 41 years old.

Condition before surgery:

Visual acuity in the distance: Vis OD = 0.03 Sph -7.5 D Cyl -1.0 D Ax 170 = 0.9

Vis OS = 0.04 Sph -7.0 D Cyl -1.0 D Ax 180 = 0.9

Corneal thickness: 510 microns.

Diagnosis: high degree stationary myopia, complex myopic astigmatism in both eyes.

The operation in accordance with the proposed invention.

First series of pulses Second series of pulses Third series of pulses "Sigma" (σ) along the weak axis, mm 2.23 2.10 2.03 Sigma (σ) along the strong axis, mm 2.08 1.96 1.89 Amplitude of energy density (A), mJ / sq.cm 140 140 140 The number of pulses along the stroma of the cornea 620 410 165

Condition after surgery (4 months):

Visual acuity in the distance: Vis OD = 0.9 Vis OS = 0.9

Corneal thickness: 445 microns, the cornea is transparent.

Minimization of the volume of removed eye tissues is achieved by the whole set of technological methods for performing laser irradiation on the cornea of the eye by simultaneously combining all removal techniques with each exposure and the logically necessary combination of these techniques and their parameters to create each of the optical surfaces and preserve the maximum volume of corneal tissue of their own.

Compared with the prototype, the author was able to reduce the volume of removed (ablated) corneal tissue by at least 30%. Since the negative response of the cornea to the laser irradiation is directly proportional to the volume of ablated tissue, the use of the invention allows to reduce the likelihood of postoperative complications.

A sequential change in the standard deviation of the Gaussian radial distribution of the energy density of the beam ("sigma") is made by setting up the laser system "Profile-500", which does not require changes in its design.

Using the proposed invention on the Profile-500 installation made it possible to confirm an unambiguous positive solution to the claimed technical problem: developing a method for surgical correction of myopia - reducing trauma to eye tissues while reducing postoperative complications, reducing the volume of removed eye tissues.

Claims (1)

A method of surgical correction of myopic astigmatism, which consists in treating the cornea by layer-by-layer ablation by pulsed radiation of a non-scanning excimer laser with a Gaussian radial distribution of energy density in the beam cross section, characterized in that the effect is performed by sequentially reducing the standard deviation of the energy density distribution in each of the following series pulses in the range from 2.7 to 1.8 mm, while the value of the amplitude of the energy density at the center of symmetry of the pulse lies in the range from 100 to 175 mJ / cm2 and remains constant throughout the series of pulses; inside each series of pulses, the value of the standard deviation of the energy density distribution is constant; moreover, each series of pulses forms ellipsoidal surfaces concave with respect to the initial surface of the cornea, located on one axis, and the impact zone is symmetrical with respect to the optical center of symmetry of the cornea; initially determine the position of the weak axis of astigmatism and combine with it the large axis of the formed ellipsoidal surfaces; then form the first concave ellipsoidal surface, the ratio of the length of the major axis of the concave ellipsoidal surface to the diameter of the cornea lies in the range from 0.6 to 0.8; then form a second concave ellipsoidal surface, and the ratio of the length of the major axis of the second ellipsoidal surface to the length of the major axis of the first ellipsoidal surface is in the range from 0.8 to 0.95; then form a third concave ellipsoidal surface, the ratio of the length of the major axis of the third ellipsoidal surface to the length of the major axis of the second ellipsoidal surface lies in the range from 0.8 to 0.95, and the exposure of the cornea is produced by excimer laser radiation with a wavelength of 193-250 nm, with a laser zone diameter from 5 to 9 mm, a pulse duration of 15-30 ns, and a pulse repetition rate of 5 to 15 Hz.

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