RU2644850C1 - Method for forming intrastomal pocket for keratoprosthesis implantation using femtosecond laser - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention relates to the field of medicine, namely to ophthalmology, and can be used to form an intrastromal pocket (ISP) when implanting keratoprosthesis using femtosecond laser. Donor corneal is placed on an artificial anterior chamber (AAC), after the AAC mechanism is closed, it is filled with the medium for corneal conservation till the condition of corneal normotension. After performing the centeration and achieving the optimum corneal compression, femtodissection of the corneal is carried out, forming an intrastromal ring pocket, and then an entrance tunnel into it, corresponding to the implantable support of the keratoprosthesis. In this case, the depth of formation of the ISP is 600 micrometer, the outer diameter of the ISP is 8.2 mm, the internal diameter of the ISP is 8.0 mm, the width of the intrastromal tunnel is 5.7 mm, the angle of the plane of formation of the intrastromal tunnel in relation to the ISP – 90°. After the completion of the femtodissection stage, the corneal fixed in the AAC is placed under the operating microscope, the remaied collagenous bridges are separated with a thin spatula along the entire circle of the intrastromal pocket.

EFFECT: method provides the minimum risk of perforation of the deep corneal layers and reduces the risk of keratoprosthesis protrusion by forming a uniform ISP on the donor's corneal, the advantage of which is the controlled depth and the optimal profile of the incision.

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Description

The invention relates to medicine, and more particularly to ophthalmology, and can be used to form an intrastromal pocket (ISK) for implanting a keratoprosthesis using a femtosecond laser.

A known method of keratoprosthetics of complicated vascular sores of 4-5 categories, comprising cutting a donor cornea into 2/3 of its thickness, followed by implantation of a keratoprosthesis and obtaining a corneal prosthetic complex (RF Patent 2523342). However, the manual method of forming corneal artery disease has several disadvantages. In particular, during the stratification of the deep layers of the stroma, the risk of perforation is high, which complicates or makes impossible the subsequent implantation of the keratoprosthesis base plate. The modern and innovative stage in the evolution of corneal surgery was the introduction of a femtosecond laser, which has prospects for solving the above problems. It provides precision cuts for the formation of ISK, which increases the safety and speed of surgery. The quality of the incisions performed by the femtosecond hardware technique significantly exceeds the manual technique using mechanical delaminators, and the ability to perform a programmed incision at a precisely set level eliminates the risk of corneal tissue injuries.

The closest analogue is a method for the formation of ISK during keratoprosthetics of complicated vascular sanguine 4-5 categories. The method consists in the fact that the allogeneic donor cornea is subjected to corneal collagen cross-linking. Then in the donor cornea form ISK. A keratoprosthesis is implanted in it, followed by obtaining a corneal prosthetic complex. The corneal-prosthetic complex is placed in a trepanation bed with its subsequent fixation to the thoracic tissue with interrupted sutures. The incision area and the corneal-prosthetic complex are covered with a separated conjunctival flap and fixed to the surrounding tissues with interrupted sutures. (RF patent 2523342).

However, in the indicated method, intended for keratoprosthetics of complicated vascular sores of category 4-5, the formation of ISK is performed manually using a mechanical delaminator, which increases the risk of corneal tissue injury and the development of intraoperative and postoperative complications associated with possible perforation, as well as the formation of uneven depth and irregular in shape.

The objective of the invention is to provide a method for the formation of ISK for implantation of a keratoprosthesis using a femtosecond laser.

The technical result achieved by using the invention is the possibility of forming a uniform ISK on the cornea of the donor, the advantage of which is a controlled depth and optimal profile of the incision, which minimizes the risk of perforation of the deep layers of the cornea and can reduce the risk of keratoprosthesis protrusion.

The technical result is achieved by the fact that in the method of forming an ISK for implanting a keratoprosthesis, according to the invention, the donor cornea is placed on an artificial anterior chamber (IPC), after closing the IPC mechanism, it is filled with medium for preserving the cornea to the state of normotonia of the cornea, after centering and achieving optimal compression cornea, perform corneal femtodissection, forming an intrastromal annular pocket, and then an entrance tunnel into it, corresponding to the implanted supporting part ke rat prosthesis, while the depth of formation of the ISK is 600 microns; outer diameter of the ISK - 8.2 mm; ISK inner diameter - 8.0 mm; the width of the intrastromal tunnel is 5.7 mm; the angle of the plane of formation of the intrastromal tunnel with respect to the ISK plane is 90 °; after the femtodissection stage is completed, the cornea fixed in the IPC is placed under an operating microscope, the remaining collagen lintels are separated with a thin spatula along the entire circumference of the intrastromal pocket.

The method is as follows.

At the first stage, the donor cornea is removed from the cornea preservation medium (corneal storage solution TU No. 9398-013-29039336-2008, manufactured by NEP Eye Microsurgery LLC, Moscow, Beskudnikovsky Blvd, 59A) and placed on IPC. After the IPC mechanism is closed, it is filled with cornea preservation medium to the state of the cornea normotonia, which is important for proper applanation. The formation of the ISK is carried out using a femtosecond laser using the above parameters of the ISK. They perform centering and achieve optimal corneal compression, perform corneal femtodissection with the formation of an intrastromal annular pocket, and then the entrance tunnel in terms of the size of the implanted supporting part of the keratoprosthesis. After the femtodissection stage is completed, the cornea fixed in the IPC is placed under an operating microscope. With a thin spatula, collagen lintels are divided around the entire circumference of the intrastromal pocket. The second stage is the implantation of the supporting part of the keratoprosthesis into the already formed CSF, the incision area is fixed with interrupted sutures. The resulting complex is placed in a medium for storing the cornea. The next day after the patient’s sedation under local anesthesia, a through trepanation of the cornea of the recipient is performed. The corneal-prosthetic complex is placed in a trepanation bed in the recipient's throat and fixed with 10-0 nylon interrupted sutures.

As a femtosecond laser, the Femto LDV Z8 model (Ziemer, Switzerland) can be used.

The proposed method is illustrated by the following examples.

Example 1: A donor cornea is removed from cornea preservation medium and placed on an IPC. After the mechanism is closed, the IPCs proceed to the formation of the ISK using a Femto LDV Z8 femtosecond laser (Ziemer, Switzerland) using radiation with a wavelength of 1020 nm, a pulse repetition rate of 200 femtoseconds (f / s), and a pulse energy of less than 100 nJ and power exposure in the stromal plane 100% (1000 mW). With the specified parameters, ISKs perform centering and achieve optimal corneal compression, perform corneal femtodissection with the formation of an intrastromal ring-shaped pocket, and then the entrance tunnel. After completing the femtodissection phase, the cornea, fixed in the IPC, is placed under an operating microscope to separate the remaining collagen jumpers around the entire circumference of the ISK.

Example 2: A donor cornea is placed on an IPC after extraction from cornea preservation medium. After closing the mechanism, the IPCs proceed to the formation of the ISK using a femtosecond laser of the Femto LDV Z8 model (Ziemer, Switzerland) using radiation with a wavelength of 1060 nm, a pulse repetition rate of 500 f / s, a pulse energy of less than 100 nJ and an exposure power of stromal plane 100% (1000 mW). With the specified parameters, ISKs perform centering and achieve optimal corneal compression, perform corneal femtodissection with the formation of an intrastromal ring-shaped pocket, and then the entrance tunnel. After completing the femtodissection phase, the cornea, fixed in the IPC, is placed under an operating microscope to separate the remaining collagen jumpers around the entire circumference of the ISK.

Thus, the proposed invention of the formation of ISK for implantation of a keratoprosthesis using a femtosecond laser allows you to clearly dose the depth of the keratoprosthesis and the uniformity of the intrastromal bed.

Claims (1)

A method of forming an intrastromal pocket for keratoprosthesis implantation, characterized in that the donor cornea is placed on the artificial anterior chamber (IPC), after closing the IPC mechanism, it is filled with cornea preservation medium to the state of the cornea normotonia, after centering and achieving optimal corneal compression, corneal femtodissection is performed, forming an intrastromal annular pocket (ISK), and then an entrance tunnel into it, corresponding to the implantable supporting part of the keratoprosthesis, at the depth of ISK formation is 600 μm, the external diameter of the ISK is 8.2 mm, the internal diameter of the ISK is 8.0 mm, the width of the intrastromal tunnel is 5.7 mm, the angle of the plane of formation of the intrastromal tunnel with respect to the plane of the ISK is 90 °, after At the end of the femtodissection phase, the cornea fixed in the IPC is placed under an operating microscope, and the remaining collagen lintels are separated with a thin spatula around the entire circumference of the intrastromal pocket.