RU2484788C2 - Intraocular lens and method of its implantation - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: group of inventions relates to field of medicine and medical equipment, namely to ophthalmosurgery and is intended for correction of aphakia after extracapcular cataract extraction. Construction of elastic intraocular lens (IOL) is such that length of plane haptic part exceeds size of posterior leaf of lens capsule sac (LCS) and haptic elements are bent in anterior-posterior direction, imitating recovery of ablated crystalline lens volume. Haptic elements have area of the smallest width, with haptic elements having in area of the smallest width and to distal edge. holes of mesh structure, which play role of markers for intra-operative making directed perpendicular to longitudinal IOL axis incisions between them Haptic elements have bifurcated end and when bent rest against anterior LCS leaf Method of intraocular lens implantation is realised by performing anterior continuous capsulorexis, cataract phacoemulsification and IOL implantation with endocapsular fixation Before operation LCS diameter is determined, cuts in form of incisions between holes in its mesh structure, directed perpendicular to longitudinal IOL axis, are made intra-operatively Cut length is dosed depending on required degree of LCS volume recovery, location of cuts being determined depending on LCS diameter.

EFFECT: application of group of inventions will make it possible to increase quality of LCS shape reconstruction, increase lens self-centering in eye due to possibility of regulating degree of bent of IOL haptic elements by intra-operative dosing their rigidity.

2 cl, 3 dwg

Description

The invention relates to medicine, namely to ophthalmic surgery, and is intended for the correction of aphakia after extracapsular cataract extraction.

Currently, there are several tasks in cataract microsurgery, the solutions of which are occupied by all manufacturers of intraocular lenses (IOLs).

One of the actively solved problems is the problem of secondary cataract (clouding of the posterior wall of the capsule in the eye with an implanted IOL). It is believed that one of the main causes of secondary cataracts is the penetration of epithelial cells of the lens masses, not removed during the operation, between the lens and the wall of the capsule. As a result of their growth, opaque lens fibers form, which form a cloudy film, which inevitably impairs the patient’s vision. Vision can be restored by additional surgery, however, it is in the patient’s interest to ensure that no reoperation is performed. A rather difficult task arises - to prevent the occurrence of cataracts in patients even in those cases when the lens masses are not completely removed during the operation.

Another task of cataract microsurgery is to restore the anatomical and topographic relationship of the eye after removing the lens from it. The fact is that most of the elastic IOLs used in cataract surgery have a thickness of about 1.0 mm, while the thickness of the lens of the human eye is within 3.7-5.5 mm. Thus, due to a significant difference in their volumes, the initial anatomical relationships in the eye are violated, which is accompanied by both changes in the capsular bag of the lens (KMX) and the appearance of complications due to a possible forward displacement of the vitreous.

Known elastic intraocular lens according to the patent of the Russian Federation 2208418, the design of which we take as a prototype. The lens contains the optical part and planar haptic elements, the length of which exceeds the size of the back sheet KMX.

Haptic elements contain several zones of variable thickness (rigidity), which provides the effect of folding the haptic elements in the anteroposterior direction.

Due to the effect of lens bending from the plane, the optical part of the prototype is tightly contacted with CMX, the equatorial zone of the lens is blocked, which prevents the penetration of epithelial cells of the lens masses, which prevents the development of secondary cataract. The presence of a prototype of a size exceeding the size of the posterior leaf of KMX allows, when placing the lens in KMX, to significantly replenish the volume of the removed lens, which is a preventive measure for the occurrence of vitreoretinal complications. Thus, the technical result of the prototype allows to solve the problem of restoring the anatomical and topographic relationships of the eye after removing the lens from it. However, the design of the prototype has disadvantages. During implantation, the haptic elements of the prototype are bent and twisted in the region of their smallest thickness (rigidity) when they rest in the capsule arches of the KMX. The disadvantages of the prototype is that when bent, the haptic elements form a rectangular edge and unevenly stretch the KXM more in the direction of these edges and along the axis of the haptic part than in the direction perpendicular to it. When resting on the KMX arches, the rectangular edge creates an uneven load distribution along the edge length, namely, the load is concentrated on its two right angles. Such an effect leads to a distortion of the CMC shape, and an unequal load on the ligamentous apparatus of the lens, self-centering of the lens in the eye is difficult, which greatly limits the successful application of this IOL model.

The purpose of the invention (device) is the creation of an elastic IOL that, when resting on the KMX equator, provides an adjustable bend of the haptic part, which closely repeats the anatomical profile and the circular form of KMX.

The technical result is achieved by the creation of an IOL, in which the haptic elements have a region of smallest width, while in the region of the smallest width and to the distal edge, the haptic elements have markers in the form of mesh openings for intraoperatively performing notches between them, perpendicular to the longitudinal axis of the IOL, also haptic elements have a bifurcated ending and, when folded, abut against the front sheet of the KXM. Before the operation, the surgeon determines the diameter of the BMC and during the operation with scissors performs a metered dissection of the jumpers in the haptic part of the IOL, interconnecting the holes (markers) of its mesh structure (in the zone of least rigidity) directed perpendicular to the longitudinal axis of the IOL. At the same time, the length of the slots and their location are determined by individual preoperative CMC parameters. Thus, the most accurate hit of the zone of least rigidity of the haptic part of the IOL is achieved in the equatorial zone of the KMX, which contributes to the optimal repetition of its shape.

There is a method of implanting an IOL, in which the length of the haptic part exceeds the size of the back leaf of the capsular bag of the lens described in RF patent 2208418, which we take as a prototype. This method consists in the fact that after performing a cataract incision, pupil dilation, circular capsulorexis with a diameter of 6-7 mm, the nucleus and lens mass are removed. The IOL is fixed in the tweezers so that the lower haptic element is folded in the form of a duplicate on the outside of the lens, and in this position it is inserted into the lower capsular arch, after which the tweezers are released. During this manipulation, the IOL is additionally held by the upper haptic element with other tweezers in order to prevent the lens from pushing out when the lower haptic element is straightened in the capsule arch due to its elasticity. The upper haptic element is also folded with tweezers into the duplicate on the outside of the lens and by traction for it to the optical part of the IOL and light pressure, the haptic element is inserted beyond the edge of the capsuleectomy opening, after which the tweezers are released. The upper haptic element, due to its elasticity, begins to expand, sliding from the inside along the front leaf of the capsule, and the IOL is installed in the arches of the capsular bag. The operation is completed by sealing the front chamber and restoring its depth, after which the lens takes its final position. However, this method has drawbacks, namely, the individual anatomical parameters of the CMX are not taken into account, which can be different both in its diameter and in strength characteristics, in addition, the CMX equator is located closer to its front pole than to the back. These circumstances for the optimal recovery of the KMX form require their accounting and reproduction, which is not provided for the prototype.

The purpose of the invention (implantation method) is to improve the quality of restoration of the CMC form, to improve the self-centering of the lens in the eye due to the possibility of regulating the degree of deflection of the haptic elements of the IOL by intraoperative dosing of their rigidity.

The technical result is achieved by the fact that before the operation, the surgeon determines the diameter of the BMX, in particular, using ultrasound biomicroscopy, and during the operation, including performing anterior continuous capsulorhexis, phacoemulsification of the cataract and implantation of the IOL with endocapsular fixation, a metered dissection of the jumpers into the IOLs with scissors its haptic part, interconnecting the holes of its mesh structure. At the same time, the length of the slots and their location are determined by individual preoperative CMC parameters. Thus, the most accurate hit of the zone of least rigidity of the haptic part of the IOL is achieved in the equatorial zone of the KMX, which contributes to the optimal repetition of its shape.

With the proposed method of implanting the claimed IOL, the haptic elements in the zone of the smallest width (stiffness) are bent when resting in the capsule arches, and the capsule is tensioned in the longitudinal direction; when bent, the bifurcated distal end abuts against the front leaf of the capsule and stretches it in the transverse direction; due to the bending of the haptic elements, the lens bends from the plane to the radius of curvature of the back surface of the capsule bag, and the optical part is pressed against the back wall of the capsule bag, which ensures tension of the capsule in the anteroposterior direction. Due to this effect, the three-dimensional tension of the capsule bag occurs and the load is evenly distributed over the entire edge when it rests in the arches of the capsule bag, which simulates its full filling and the anatomical and topographic parameters approach pre-operative ones, and the best stabilization of the lens in the patient’s eye is ensured. With this property of the design, which implements three-dimensional tension of the capsule, provides better, in comparison with the prototype, the self-centering of the lens in the CMX and the reproduction of its shape. Due to the fact that the distal ends of the haptic elements are softer than the proximal and the capsule is three-dimensionally stretched, there is no strong bending of the lens in the anteroposterior direction and the optical part does not go closer to the retina.

The proposed method of IOL implantation successfully passed the experimental and clinical part of the study at the Department of Ophthalmology, GOU DPO PIUV Roszdrav from October 2010 to February 2011 in 6 eyes of 6 patients, which makes it possible to characterize it as a safe and affordable method that expands the possibilities of this type of IOL to restore a more uniform CMH forms after cataract removal.

The claimed invention is illustrated in graphic material.

Figure 1 - elastic intraocular lens.

The intraocular lens consists of the optical part (1) and haptic elements, which contain the zone of smallest width (2) and the bifurcated distal end (3). Haptic elements in the region, starting from the region of smallest width and to the distal edge of the haptic, have markers in the form of holes in the mesh structure (4) for intraoperatively performing notches between them, perpendicular to the longitudinal axis of the IOL, of notches, providing an improvement in the quality of restoration of the CMX shape.

Figure 2 - position of the intraocular lens in the capsular bag.

Due to the bending of the haptic elements, the lens bends from the plane to the radius of curvature of the back surface of the capsule bag, the optical part is pressed against the back wall of the capsule bag, which ensures tension of the capsule in the anteroposterior direction. In the place where notches are made intraoperatively between the holes (markers), directed perpendicular to the longitudinal axis of the IOL, a bend area is formed.

Figure 3 - position of the intraocular lens in the capsular bag,

During implantation, the haptic elements in the zone of the smallest width (2) are bent along the line with an emphasis on the capsule arches, and the capsule is tensioned in the longitudinal direction (5); when bent, the bifurcated distal end abuts against the front leaf of the capsule and stretches it in the transverse direction (6).

Claims (2)

1. An elastic intraocular lens (IOL), in which the length of the planar haptic part exceeds the size of the posterior leaf of the capsule lens bag (CMX), and the haptic elements are bent in the anteroposterior direction, simulating the filling of the volume of the distant lens, characterized in that the haptic elements have a region of smallest width while in the region of the smallest width and to the distal edge, the haptic elements have openings of a mesh structure, which play the role of markers for intraoperative performance between them directed perpendicularly relative to the longitudinal axis of the IOL of the notches, and the haptic elements have a bifurcated end and, when bent, abut against the front sheet of the KXM. 2. A method for implanting an intraocular lens (IOL) by performing anterior continuous capsulorhexis, cataract phacoemulsification and implantation of an IOL with endocapsular fixation, characterized in that prior to the operation, the CMX diameter is determined; directed perpendicularly relative to the longitudinal axis of the IOL, while the length of the slots is dosed depending on the required degree of replenishment of the volume of CMX, and the location of the slots determined depending on the diameter of the CMX.

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