RU2345741C1 - Method of intraocular vision correction in case of crystalline lens ectopia of i-ii degree - Google Patents

Abstract

FIELD: medicine, ophthalmology.

SUBSTANCE: invention can be used for intraocular vision correction in cases when crystalline lens is displaced relative to eye optic axis, i.e. when fibres of crystalline lens Zinn zonule are weakened in one of sectors (stretched or torn), and crystalline lens equator in region of weakened zonule does not reach eye optic axis (ectopia of I-II degree). Through small tunnel access concentrically to point in which eye optic axis crosses crystalline lens front capsule, anterior capsulorexis is performed. Content of capsule sac is removed. Into capsule sac elastic mono-block intraocular lens (IOL) with support elements of S-shaped form is implanted. After introduction of IOL into capsule sac it is installed with longitudinal axis along vector of crystalline lens displacement. 1 mm long linear cut along capsule sac equator is performed. Place of the cut is determined visually by place of intersection of lens support element with crystalline lens equator when IOL is superposed on cornea and projected on crystalline lens equator plane, superposing optical centres of IOL and cornea and superposing longitudinal axis of lens with vector of crystalline lens displacement. After making the cut, IOL is rotated in sac equator plane counterclockwise until distal end of lower support element reaches the cut on equator. Then said support element is introduced into the cut and moved behind sac until IOL optic part is installed into central position.

EFFECT: reduction of post-operation complications due to reduction of traumaticity and minimising number of manipulations in capsule sac, achieving high vision acuity.

3 cl, 1 ex

Description

The invention relates to the field of medicine - ophthalmology and can be used for intraocular vision correction in cases when the lens is displaced relative to the optical axis of the eye, i.e. the fibers of the zinnic ligament of the lens in some sector are weakened (stretched or torn), while the equator of the lens in the zone of weakened ligaments does not reach the optical axis of the eye (ectopy of the I-II degree).

There are a number of methods for intraocular vision correction in ectopia of the lens of the I-II degree. Of course, surgeons seek to correct their vision using an intraocular lens (IOL) implanted in a capsular bag. In situations where the lens is displaced from the optical axis of the eye, and in some cases, as in Marfan’s syndrome, the lens is not only displaced, but still smaller, one of the methods for centered fixing the IOL in the capsule bag is to shorten the length of one of the supporting elements .

The closest solution to the claimed technology is the method developed in our Center, in which surgery is performed through a small tunnel incision, capsulorexis is performed concentrically at the point of intersection of the optical axis of the eye with the anterior capsule of the lens, the contents of the capsular bag are removed by phacoemulsification, and one of the most of modern lenses - Alcon's Acrysof, is an elastic folding three-part lens, one of the supporting elements of which is partially cut off before implantation (RF Patent No. 2272602 - otip).

The disadvantage of this method is that it is possible to use this technology if the lens is displaced and its size is smaller than the standard one (for example, with Marfan syndrome), but in the case when the lens is only displaced relative to the optical axis of the eye, and its size is normal, then in such a situation the position of the IOL in the bag will not always be fixed (since the dimensions of the lens become smaller), and therefore centered.

The objective of the invention is to develop a reliable method of intraocular vision correction for ectopia of the crystalline lens of the I-II degree, which will be applicable to Marfan syndrome.

The technical result obtained by solving this problem is to reduce postoperative complications, high visual acuity.

The indicated technical result can be obtained if in the method of intraocular vision correction for ectopia of the crystalline lens of the I-II degree, including performing through the small tunnel access capsulorexis, concentrically at the point of intersection of the optical axis of the eye with the anterior capsule of the lens, removing the contents of the capsular bag and implanting an elastic intraocular lens ( IOL) with S-shaped support elements in a capsule bag, the lens being mounted in the bag with a longitudinal axis along the lens displacement vector, according to For retraction, a monoblock lens is used as an IOL; after inserting it into the bag, a linear incision is made along the equator of the capsular bag 1 mm long, the location of the incision is determined visually at the intersection of the lens support element with the lens equator when applying the IOL to the cornea and projecting it onto the equatorial plane of the lens, combining the optical centers of the IOL and the cornea, as well as the longitudinal axis of the lens with the lens displacement vector, after performing the incision, the IOL begin to rotate in the equatorial plane bag and counterclockwise until the distal end of the lower section of the support element on the equator, then the supporting element lead into the incision and is advanced over the bag to establish the optical portion of the IOL in a central position. As a private option, Acrysof lens is used as an elastic monoblock lens. If necessary, the incision along the equator of the capsular bag is expanded.

Among the essential features characterizing the method, the distinguishing ones are:

- as the IOL use an elastic monoblock lens,

- after the IOL is inserted into the bag, a linear section is made along the equator of the capsular bag 1 mm long,

- the position of the incision is determined visually at the intersection of the lens support element with the lens equator when applying the IOL to the cornea and projecting it onto the equatorial plane of the lens, combining the optical centers of the IOL and the cornea, as well as the longitudinal axis of the lens with the lens displacement vector,

- after performing the incision, the IOL begins to rotate in the equatorial plane of the bag counterclockwise until the distal end of the lower supporting element of the incision at the equator,

- then the support element is inserted into the section and is advanced behind the bag until the optical part of the IOL is established in the central position.

Between the totality of essential features and the achieved technical result, there is a causal relationship.

In the developed technology, the lens remains intact, its supporting element is not shortened, and at the same time, the lens in the eye occupies a central position, although the lens is displaced relative to the optical axis of the eye. This is achieved due to the fact that one of the supporting elements through the incision in the equatorial part of the bag is discharged behind the bag and is located in the ciliary groove. In order to carry out this stage of the operation with low invasiveness, with a minimum number of actions in the bag, you must follow the sequence of actions described in the claims. Firstly, initially the lens is mounted in the bag with the longitudinal axis along the lens displacement vector, then a cut is made along the equator of the capsule bag (this is the area where the fibers of the zinc ligament are torn or stretched), and then the IOL starts to rotate counterclockwise in the equatorial plane of the bag until it reaches the distal end of the lower supporting section element at the equator. In this case, an elastic monoblock lens with S-shaped support elements is used. It is the constructive implementation of the lens support elements (S-shaped) that determines this sequence of actions. When the distal end of the lower support element reaches the incision at the equator, it is led into the incision and further advanced, reaching the central position of the lens relative to the optical axis of the eye. Having given a central position at the final stage of implantation of the lens and, in particular, optics, the lens is again placed by its longitudinal axis along the lens displacement vector, because the doctor determined the incision site in advance, visually at the intersection of the lens support element with the lens equator when applying the IOL to the cornea , and projected it onto the equatorial plane of the lens, while combining the optical centers of the IOL and the cornea, as well as the longitudinal axis of the lens with the lens displacement vector. Since the support element of the monoblock lens has a different cross-sectional length, therefore, for some situations (depending on the magnitude of the lens displacement) a 1 mm cut will not be enough for the support element to fit into it, in these cases, the incision is expanded, right at the time of the establishment of a supporting element in it. A monoblock lens, unlike a three-part one, is reliably and stably held in the postoperative period in the position in which the surgeon finally establishes it.

The lens with this technology turns out to be fixed in the eye at three points: in the ciliary groove - there is a support element brought out by the bag, in the equator of the bag - there is a second support element and in the section of the equator, through which the support element is taken out of the bag zone. The fixation is reliable, while the lens is centered.

The method is as follows. The beginning of the operation is traditional. Through a small tunnel incision, capsulorexis is performed. It is decentered relative to the bag, but centered relative to the optical axis of the eye. Remove the contents of the bag by phacoemulsification. Then, before inserting the IOL into the bag, the lens (monoblock Alrys Acrysof Natural) is placed on the cornea, the optical center of the cornea and lens is aligned, and the longitudinal axis of the lens is aligned with the lens displacement vector, and the intersection of the IOL support element with the lens equator is visually determined and remembered . Then, the lens is implanted into the bag with the help of an injector, having the longitudinal axis along the lens displacement vector. Then, using a vascular knife at the equator, a 1 mm long incision is made in the place where the surgeon had just observed the intersection of the support element with the bag equator (zone of weakened fibers of the zinc ligament). After that, the lens is rotated in the equatorial plane of the bag counterclockwise (namely counterclockwise, because this is due to the design of the lens with S-shaped support elements). The distal end of the lower support element is brought into the section, and so advanced in the section so that the IOL optics is in the central position. Finish the operation traditionally.

Example. Patient K., 15 years old, came to our center with a diagnosis of Marfan syndrome: ectopia of the crystalline lens of the 1st degree, amblyopia in the left eye.

On examination: OS - visual acuity - 0.04.

The operation according to the invention is completed. An Acrysof Natural monoblock folding lens (model SN60AT) was implanted; one of the supporting elements was pulled out behind a capsular bag and placed in a ciliary groove.

When viewed on the third day after the operation: visual acuity of the left eye 0.3 with correction, the lens occupies a central position.

After 6 months, visual acuity OS 0.4 with correction. The lens is in the correct center position.

In the Yekaterinburg Center, this method performed 7 eye operations with an ectopy of the I-II degree. All operations were performed without complications, elastic monoblock lenses were successfully implanted into the bag, and then centered by removing one of the supporting elements outside the bag zone through an incision in the equator of the capsular bag. In the postoperative period, complications were not observed.

Claims (3)

1. A method of intraocular vision correction for ectopia of the crystalline lens of the I-II degree, comprising performing through a small tunnel access capsulorexis concentrically at the point of intersection of the optical axis of the eye with the anterior capsule of the lens, removing the contents of the capsular bag and implanting an elastic intraocular lens (IOL) with S-shaped support elements forms in the capsule bag, the lens being installed in the bag with a longitudinal axis along the lens displacement vector, characterized in that a single-block lens is used as the IOL whose places in the bag carry out a linear section along the equator of the capsular bag 1 mm long, the location of the section is determined visually by the intersection of the lens support element with the lens equator when applying the IOL to the cornea and projecting it onto the equatorial plane of the lens, combining the optical centers of the IOL and the cornea, as well as the longitudinal axis of the lens with the lens displacement vector, after the incision is made, the IOLs begin to rotate counterclockwise in the equatorial plane of the bag until the distal The lower support element of the cut at the equator, then the support element is inserted into the cut and is advanced behind the bag until the optical part of the IOL is established in the central position. 2. The method according to claim 1, characterized in that the Acrysof lens is used as an elastic monoblock lens. 3. The method according to claim 1, characterized in that, if necessary, the incision along the equator of the capsular bag is expanded.