RU2688955C1 - Method of femtolaser refractive autokeratoplasty in keratoconus - Google Patents

Abstract

FIELD: medicine.SUBSTANCE: invention relates to ophthalmology. For femtosynthetic refractive autokeratoplasty in keratoconus with average keratometry values <55 dioptres. performing corneal resection by femtosecond laser, during which an annular incision of the cornea is performed, passing at distance of 1.5–2.0 mm from the limb area, at an angle to the surface of the cornea, at a depth of up to 90 % of the thickness of the cornea. Second annular incision of cornea passes perpendicular to its surface, at a distance from first, so that these sections crossed at a given depth and formed a ring-shaped flap of corneal tissue with a wedge-shaped profile, after removal of which the corneal wound edges are closed. Both annular incisions of the cornea are performed within the framework of one femto laser procedure, and distance between incisions is calculated by formulawhere S - distance between annular incisions of cornea; h is the height of the keratoconus based on the optical spectral coherence tomography (OSCT) of the anterior segment of the eye; d is keratoconus base diameter according to anterior eye CT scan; R is planned radius of corneal curvature.EFFECT: method provides accurate, graduated corneal resection with consideration of individual corneal parameters of the patient, flattening of the cornea to the calculated values, improved corrected and uncorrected visual acuity.1 cl, 2 ex

Description

The invention relates to medicine, namely to ophthalmology, and can be used to conduct femtolaser refractive autokeratoplasty with keratoconus with average keratometry values <55 diopters.

Keratoconus is a progressive degenerative non-inflammatory disease of the cornea, characterized by thinning, weakening and ectasia of its paraxial zones, which leads to uneven corneal surface and, as a consequence, gross violations of visual functions.

The urgency of the problem of treating keratoconus is associated with the prevalence of the disease, the early debut of the disease, as well as the progressive nature of the course, leading to a significant loss of visual function and disability through vision [1].

Currently, significant progress has been made in the treatment of early stages of the disease. The use of crosslinking, the implantation of various models of the intrastromal segments and rings, as well as the combination of these techniques, can improve vision and stabilize the course of the pathological process [5].

However, in the treatment of the advanced stages of keratoconus, the rehabilitation of patients depends largely on the availability of donor material and the possibility of corneal transplantation. Layered keratoplasty techniques (DALK) only partly solve the problem of chronic shortage of donor corneal tissue.

The search for alternative methods of treating the distant stages of keratoconus that do not require the use of donor material has led to the development of a femtolaser refractive autokeratoplasty technique (FRAC) [2–4]. The therapeutic (refractive) effect of the operation is achieved by flattening the own cornea, giving it a more physiological shape and curvature. The objective advantages of the FRAAC are the absence of the need for donor corneas, the absence of the risk of developing an immune conflict, the non-penetrating nature of the operation, the preservation of its own endothelium.

There is a method of femtolaser refractive autokeratoplasty [patent for EAPO patent 026805], which involves performing cornea resection using a femtosecond laser, which produces an annular incision of the cornea, passing at a distance of 1.5-2.0 mm from the limbus, at an angle to the cornea surface, to a depth of 90% of the thickness of the cornea, the second annular incision of the cornea is performed perpendicular to its surface, at a distance from the first, so that these incisions intersect at a predetermined depth and form a ring-shaped a flap of corneal tissue with a wedge-shaped profile, after removal of which the edges of the corneal wound are sutured.

The disadvantages of this method are the two-stage execution of the annular incisions of the cornea, which reduces the precision of the operation; the lack of consideration of individual parameters of the cornea of the patient when determining the distance between two annular cuts, and, consequently, the lack of dosing during the formation of a ring-shaped flap of the corneal tissue with a wedge-shaped profile, an insufficiently predictable refractive effect of the operation.

The objective of the invention is the creation of an effective personalized method of femtolaser refractive autokeratoplasty in keratoconus.

The technical result of the proposed method is accurate, metered resection of the corneal tissue, taking into account the individual parameters of the patient's cornea, flattening the cornea to the calculated values, improving corrected and uncorrected visual acuity.

The technical result is achieved in that in the method of femtolaser refractive autokeratoplasty in keratoconus, including performing cornea resection using a femtosecond laser, during which an annular incision of the cornea is made, passing at a distance of 1.5-2.0 mm from the limbus area at an angle to the surface the cornea, to a depth of 90% of the thickness of the cornea, the second annular incision of the cornea runs perpendicular to its surface, at a distance from the first, so that these incisions intersect at a given depth and an annular flap of corneal tissue with a wedge-shaped profile is formed, after removal of which the edges of the corneal wound are sutured, according to the invention, both annular incisions of the cornea are performed within one femtolaser procedure, including setting resection parameters on a femtosecond laser working panel, docking, vacuum set, centering of the femtolaser resection projection , conducting two annular cuts, and the distance between the cuts is calculated by the formula:

where S is the distance between the annular corneal incisions;

h is the height of keratoconus according to spectral optical coherence tomography (SOCT) of the anterior segment of the eye;

d is the diameter of the base of keratoconus according to the SOC of the anterior segment of the eye;

R - the planned radius of curvature of the cornea.

The technical result is achieved due to the fact that:

1) both annular incisions of the cornea are performed in the framework of one femtolaser procedure, including setting the resection parameters on the femtosecond laser working panel, docking, vacuum set, concentration of the femtolaser resection projection, conducting two annular incisions;

2) the distance between the annular incisions of the cornea is determined taking into account the individual parameters of the patient’s cornea, namely, the height and diameter of the base of keratoconus according to the SOC of the anterior segment of the eye, biometrics, which allows to calculate the required parameters of cornea resection necessary to flatten the cornea to the calculated values.

The method is as follows.

Using the data of biometrics, determine the theoretical value of keratometry and the radius of curvature of the anterior surface of the cornea, necessary for emmetropic refraction of the eye. It is known that with an increase or decrease in biometrics of the eye by 1 mm, the clinical refraction of the eye is shifted by - 3 diopters. For the calculation, a schematic model of the eye of Gulstrand is used [Khatsevich, TN Medical optical devices. Physiological optics [Text]: studies. allowance. 3rd ed., Corr. and add. - Novosibirsk: SSGA, 2010. - C 11-20]. The deviation of the actual biometrics from 23.4 mm is compensated by a corresponding change in the optical power of the anterior surface of the cornea, equal to 48.83 dptr, necessary for emmetropic refraction of the eye.

The calculated radius of curvature of the front surface is determined by the formula:

F = 1000 (n-1) / R, where F is the optical power of the anterior surface of the cornea, n is the refractive index of the cornea, equal to 1.376, and R is the radius of curvature of the anterior surface of the cornea. Transforming the formula, we get R = 1000 (n-1) / F.

To calculate the distance between the annular incisions and the corresponding diameters of the corneal cuts, the patient is performed a SSCT of the anterior segment of the eye on the RTVue XR Avanti device (Optovue, USA). During the study, determine the values: h - the height of keratoconus, d - the diameter of the base of keratoconus.

Then calculate the distance between the two annular incisions of the cornea by the formula:

where S is the distance between the annular corneal incisions;

h is the height of keratoconus according to spectral optical coherence tomography (SOCT) of the anterior segment of the eye;

d is the diameter of the base of keratoconus according to the SOC of the anterior segment of the eye;

R - the planned radius of curvature of the cornea.

The diameters of the annular cuts differ by 2 S values (D1-D2 = 2S).

On the Femto LDV Z8 femtosecond laser panel (Ziemer Ophthalmic Systems, Switzerland), the cornea resection parameters are set: the diameters of the annular incisions and the depth of the cornea resection. Carry out the docking of the working module of the femtosecond laser with the surface of the patient's eye, vacuum fixation of the interface of the femtosecond laser with the patient's eye. The femtolaser resection projection is centered on the femtosecond laser working panel. Within one femtolaser procedure, the laser makes 2 annular incisions to a depth of 90% of the minimum corneal thickness in the area of the incisions made. The angle at which the laser will perform the first annular incision is determined automatically in the femtosecond laser program after entering the values of the diameters of the annular incisions and the depth of resection of the cornea.

Thus, two annular incisions intersect at a predetermined depth and form an annular flap of corneal tissue with a wedge-shaped profile, after removal of which the edges of the corneal wound are sutured with interrupted sutures 10-0.

The invention is illustrated by the following clinical data.

According to the proposed method, 2 male patients were treated with a diagnosis of keratoconus stage 3.

Clinical example 1. Patient s., Age 39 years. Vision is stable for 5 years. Visual acuity without correction is 0.01, with correction of sph - 10.0 cyl - 4.5 = 0.09. Pachymetry - 382 microns at the top of the cone, average keratometry - 54.4 diopters, biometry - 24.01 mm.

When conducting the SSCT of the anterior segment of the eye on the RTVue XR Avanti device (Optovue, USA), the following values were determined: h - keratoconus height = 207 μm, d - keratoconus base diameter = 2620 μm.

Using the schematic model of the Gulstrand eye and patient's biometrics data, the optical power of the cornea and the radius of curvature of its front surface were determined, corresponding to emmetropic refraction of the eye. To achieve emmetropic clinical refraction of the eye with a long eye of 24.01 mm, it is necessary to reduce the optical power of the anterior surface of the cornea by 1.83 diopters (24.01-23.4 = 0.61; 0.61 × 3 = 1.83). The optical power of the front surface of the cornea in 47 diopters (48.83-1.83 = 47.00) corresponds to the curvature of the front surface (R), equal to 8 mm. The calculation was carried out according to the formula:

F = 1000 (n-1) / R, where F is the optical power of the anterior surface of the cornea, n is the refractive index of the cornea, equal to 1.376, and R is the radius of curvature of the anterior surface of the cornea. Transforming the formula, we get R = 1000 (n-1) / F; R = 1000 (1.376-1) 747; R = 8 mm.

Scheduled keratometry was also defined as the difference between the optical power of the cornea of the schematic eye (43.05-1.83 = 41.22 diopters).

Then calculated the distance between the two annular incisions of the cornea by the formula:

S = 80.222 μm, the difference in the outer diameters of the annular cuts was: S × 2 = 160.444 μm.

During the operation, the Femto LDV Z8 femtosecond laser operating panel (Ziemer Ophthalmic Systems, Switzerland) was used to set the cornea resection parameters. The working module of the femtosecond laser with the surface of the patient's eye was docked, the vacuum fixation of the interface of the femtosecond laser with the patient's eye was performed. The femtolaser resection projection was centered on the femtosecond laser working panel. Within one femtolaser procedure, the laser made 2 annular incisions to a depth of 90% of the minimum corneal thickness in the area of the incisions made. The angle at which the laser performed the first annular incision was determined automatically in the femtosecond laser program after entering the values of the diameters of the annular incisions and the depth of resection of the cornea. As a result, two annular incisions intersected at a predetermined depth and formed an annular flap of corneal tissue with a wedge-shaped profile, after removal of which the edges of the corneal wound were stitched with interrupted sutures 10-0.

The postoperative period was calm. Moderately expressed corneal syndrome was stopped for 4 days against the background of the installations of steroid anti-inflammatory drugs. The patient from the first day after surgery noted improvement in vision. After 1 week, visual acuity without correction after surgery was 0.1, with a maximum correction of 0.2. In the period of 6 months after the operation, there was an increase in both corrected visual acuity (COS) and visual acuity without correction (CICA). NKOH was 0.2, KOZ-0.5.

Indicators of keratometry after 1 week after surgery were recorded at 32.8 diopters. The depth of the anterior chamber of the eye at this time decreased from 3.59 to 2.45 mm. In the period of 6 months after surgery, the average keratometry increased to 41.2 diopters. The depth of the anterior chamber of the eye tended to recover to 3.14 mm. Postoperative astigmatism was 2.75 diopters.

Clinical example 2. Patient N., age 35 years. The vision is stable for 7 years. Visual acuity without correction is 0.02, with correction sph -12.0 cyl - 6.0 = 0.1. Pachymetry - 390 microns at the top of the cone, average keratometry - 55.1 diopters, biometry - 24.04 mm.

When performing the SSCT of the anterior segment of the eye on the RTVue XR Avanti device (Optovue, USA), the following values were determined: h - keratoconus height = 203 μm, d - keratoconus base diameter = 2610 μm.

Using the schematic model of the Gulstrand eye and patient's biometrics data, the optical power of the cornea and the radius of curvature of its front surface were determined, corresponding to emmetropic refraction of the eye. To achieve emmetropic clinical refraction of an eye with a long eye of 24.04 mm, it is necessary to reduce the optical power of the anterior surface of the cornea by 1.92 dptr (24.04-23.4 = 0.64; 0.64 × 3 = 1.92). The optical power of the anterior surface of the cornea at 46.91 dptr (48.83-1.92 = 46.91) corresponds to an anterior curvature of 8.0 mm. The calculation was carried out according to the formula:

F = 1000 (n-1) / R, where F is the optical power of the anterior surface of the cornea, n is the refractive index of the cornea, equal to 1.376, and R is the radius of curvature of the anterior surface of the cornea. Transforming the formula, we get R = 1000 (n-1) / F; R = 1000 (1,376-1) / 46,91; R = 8 mm.

Scheduled keratometry was also defined as the difference between the optical power of the cornea of the schematic eye (43.05-1.92 = 41.13 dptr).

Then calculated the distance between the two annular incisions of the cornea by the formula:

S = 77.312 μm, the difference in the outer diameters of the annular cuts was: S × 2 = 154.624 μm.

During the operation, the Femto LDV Z8 femtosecond laser operating panel (Ziemer Ophthalmic Systems, Switzerland) was used to set the cornea resection parameters. The working module of the femtosecond laser with the surface of the patient's eye was docked, the vacuum fixation of the interface of the femtosecond laser with the patient's eye was performed. The femtolaser resection projection was centered on the femtosecond laser working panel. Within one femtolaser procedure, the laser made 2 annular incisions to a depth of 90% of the minimum corneal thickness in the area of the incisions made. The angle at which the laser performed the first annular incision was determined automatically in the femtosecond laser program after entering the values of the diameters of the annular incisions and the depth of resection of the cornea. As a result, two annular incisions intersected at a predetermined depth and formed an annular flap of corneal tissue with a wedge-shaped profile, after removal of which the edges of the corneal wound were stitched with interrupted sutures 10-0.

The postoperative period was calm. Moderately expressed corneal syndrome was stopped for 5 days against the background of installations of steroid anti-inflammatory drugs. The patient from the first day after surgery noted improvement in vision. After 1 week, visual acuity without correction was 0.2, with a maximum correction of 0.3. In the period of 6 months after the operation, the increase in NKOH to 0.3 and KOZ to 0.4 was noted.

Indicators of keratometry after 1 week after surgery were recorded at 33.4 diopters. The depth of the anterior chamber of the eye at this time decreased from 3.45 to 2.22 mm. In the period of 6 months after surgery, the average keratometry increased to 41.1 diopters. The depth of the anterior chamber of the eye tended to recover to 3.07 mm. Postoperative astigmatism was 4.25 diopters.

A pronounced flattening of the cornea and a decrease in the average keratometry in the early postoperative period was due to the tension of the sutures, which was significantly reduced in a period of 6 months.

Thus, the inventive method provides an accurate, metered resection of the corneal tissue, taking into account the individual parameters of the patient's cornea, flattening the cornea to the calculated values, increasing corrected and uncorrected visual acuity.

Literature

1. Zolotorevsky A.V., Zolotorevsky K.A., Abdullaev E.E. Experience of treating patients with keratoconus and keratectasias // Clinical medicine. - 2013. - V. 5. - №1. - p. 40-44.

2. Sitnik G.V., Slonimsky A. Yu., Slonimsky Yu. B., Imshenetskaya T.A. Femtolaser refractive autokeratoplasty: a new way to treat keratoconus // Medical Journal. - Minsk: Belarusian State Medical University. - 2015. - №4. - p. 113-117.

3. Sitnik G.V., Slonimsky A.Yu., Slonimsky Yu.B. Femtolaser refractive autokeratoplasty: first results and prospects // Ophthalmology. - 2015. - V. 12. - №3. - pp. 22-29.

4. Slonimsky A.Yu., Sitnik GV, Slonimsky Yu.B., Imshenetskaya T.A. Femtolaser refractive autokeratoplasty - a new method of surgical treatment of keratoconus // Point of view. East - West. - 2016. - №1. - pp. 42-45.

5. Kymionis G.D. Long-term follow-up of corneal collagen cross-linking for keratoconus - the Cretan study // Cornea. - 2014. - Vol. 33 (10). - P. 1071-1079.

Claims (3)

The method of femtolaser refractive autokeratoplasty in keratoconus, including corneal resection using a femtosecond laser, during which an annular incision of the cornea is made, passing at a distance of 1.5-2.0 mm from the limbus area, at an angle to the surface of the cornea, to a depth of 90% the thickness of the cornea, the second annular incision of the cornea runs perpendicular to its surface, at a distance from the first, so that these incisions intersect at a given depth and a corneal flap is formed Kani with wedge-shaped profile, whose edges after removal of corneal wound is sutured, characterized in that the two annular section corneal operate within one femtolazernoy procedures, and the distance between the cuts is calculated using the formula

where S is the distance between the annular corneal incisions; h is the height of keratoconus according to spectral optical coherence tomography (SOCT) of the anterior segment of the eye; d is the diameter of the base of keratoconus according to the SOC of the anterior segment of the eye; R - the planned radius of curvature of the cornea.