WO1997017915A1 - Flexible intraocular implant - Google Patents

Abstract

A unitary intraocular implant made of a flexible material and provided with a substantially circular optical portion (50) and a haptic portion consisting of two attachment elements (52, 54) that each comprise a contact portion (56) for engaging the inner wall of the eye, as well as connecting means (58). Said contact portions have the shape of an arc of a circle with substantially the same centre as the optical portion. The length of the chord (C) adjacent to each contact portion (56) is substantially the same as the diameter (D) of the optical portion. Each connecting means (58) consists of a continuous web defined by edges (60, 62) having a regular curvature, and the distance between the two points on the web that are located on a common line perpendicular to the axis of symmetry (XX') of the implant in the direction of the attachment elements is smaller than the diameter of the optical portion.

Description

 FLEXIBLE IMPLANT

The present invention relates to a flexible intraocular implant. Intraocular implants are corrective systems for human vision that can, in a number of cases, replace contact lenses or external corrective lenses. In other cases, these implants can be combined for example with corrective lenses to obtain a suitable vision correction. An intraocular implant essentially consists of an optical part of generally circular or slightly oval shape which forms the corrective optical system itself. It also includes a haptic part which is used for positioning and fixing the optical part inside the eye in the suitable position.

The so-called cataract operation is now most often performed using the operating technique known as phacoemulsification. This technique allows the ablation of the opaque lens by the introduction into the eye of an ultrasound probe with an irrigation / aspiration system. By the combined action of ultrasound and the BBS flow, the lens is removed by emulsification.

This operating technique has the advantage over previous techniques of requiring only the making of an incision of reduced size in the cornea to introduce into the eye the material necessary for this ablation. It is therefore understood that it is advantageous to have intraocular implants which can be introduced into the interior of the eye and placed by the reduced-size incision which is only necessary during the ablation operation. of the lens. With the implants which are most often currently developed and which are produced in PMMA, that is to say in a rigid material, whatever the precautions taken for the realization of the haptic parts, the incision must necessarily have a dimension sufficient to allow at least the optical part of the implant, the diameter of which is around 6mm, to pass. To further reduce the dimensions of the implant during the introduction phase inside the eye through the incision, it has already been proposed to produce implants using flexible and hydrophilic materials known as the name of HYDROGEL. Thanks to the very great flexibility of this material, it is possible to fold or roll the implant, including its optical part, to make it pass through the incision, the implant resuming its normal shape and dimensions when it is set up in the eye.

However, because of its great flexibility, the production of the haptic part of the implant raises particular problems for ensuring proper fixation and positioning of the implant inside the eye, especially when this implant is placed in the capsular bag. It is understood in particular that it is necessary for the haptic part to develop a sufficient holding force in order to avoid the risks of ejection of the implant from the capsular bag.

To solve this problem, European patent application 579 528 describes several types of flexible implants implantable in the posterior chamber.

The attached figure shows in a simplified manner the general form of one of the embodiments described in the European patent application referred to above. This implant essentially comprises a circular optical part 10 and a haptic part constituted by two fixing elements respectively referenced 12 and 14. According to this embodiment, each fixing element comprises a contact portion 16 in the form of a semicircle. intended to come into contact with the internal wall of the eye and, more precisely, with the capsular bag, this contact portion 16 being connected to the periphery of the optical part 10 by two arms 18 and 20 which thus define them, in each fastening element, a window 22 of relatively large dimension. Such an implant effectively keeps it in place in the capsular bag effectively, avoiding the risks of ejection of the latter out of the capsular bag.

However, such an implant has certain drawbacks with regard to its placement in the eye. Because the implant is made of a flexible material such as hydrogel, the implant is introduced into the eye through an incision after this implant has been folded in. two, as shown schematically in Figure lb. The folded implant is held in this position using a surgical instrument 24 in the form of a clamp, the ends of the branches of the clamp such as 26 having three points of contact or clamping 28, 30 and 32. As a result of the presence of the windows 22 in the fastening elements of the implant, the contact points 28 and 32 of the surgical instrument hold poorly or do not maintain at all, in folded form, the fastening elements of the haptic part. As a result, these are relatively free during implantation of the implant in the eye, which, on the one hand, makes it more difficult for the implant to pass through the incision made in the cornea and, on the other hand, risks causing the contact portions 16 to break.

In addition, it can be seen that the contact portion 16 having a length greater than that of the diameter of the optical part 10, the size of the implant once folded still remains relatively large during its passage through the incision made in the cornea.

An object of the present invention is to provide an intraocular implant made of a flexible material which has characteristics such that its implantation in the eye, in particular using the tool defined above is facilitated while ensuring the same quality of maintenance of the implant in the eye after its placement.

To achieve this object, according to the invention, the monobloc intraocular implant made of a flexible material and comprising a substantially circular optical part and a haptic part consisting of two fixing elements diametrically opposite with respect to said optical part, each fixing element comprising a contact portion intended to come into contact with the internal wall of the eye and means for connecting said contact portion to the periphery of said optical part, said contact portions having the shape of an arc of circle having substantially the same center as the optical part, is characterized in that the rope supporting each contact portion has a length substantially equal to the diameter of the optical part, in that each of the connection means has the shape of a veil non-perforated extending between said contact portion and the periphery of said optical part, said veil being limited by edges having the shape of a curve with regular curvature, each curve extending between one end of the contact portion and a point on the periphery of the optical part, the two points of the edges of the veil situated on the same perpendicular to the axis of symmetry of the implant in the direction of the fastening elements being separated by a distance less than the diameter of said optical part.

It is understood that, thanks to the fact that the fastening elements are not perforated, these fastening elements will be well maintained in the folded position using the surgical instrument used for its insertion into the eye. In addition, it is understood that, thanks to the relatively reduced length of the contact portions which is of the order of magnitude of the diameter of the optical part, the transverse size of the implant once folded is reduced to the maximum since corresponds substantially to half the diameter of the optical part. Finally, it can be seen that, since each web connecting the contact portion to the periphery of the optical part, has at least one portion whose width is reduced compared to that of the contact portion and the optical part, effectively obtains, at each contact portion, an anchoring effect between the front and rear walls of the capsular bag after the implant has been placed, which ensures that the implant is maintained in the capsular bag.

According to a preferred embodiment, the optical part of the implant is limited by two surfaces, respectively anterior and posterior, in the form of spherical caps each bounded by a circle, the circle of the anterior surface having a diameter less than that of the posterior surface.

It is understood that this arrangement makes it possible to reduce the thickness of the optical part in its thickest zone, that is to say that corresponding to its optical axis while maintaining the same curvature of the rear face of the optical part. Better folding qualities of the optical part are thus obtained, due to the reduction in its thickness while maintaining the same quality of contact of the posterior face of the implant on the posterior wall of the capsular bag.

Other characteristics and advantages of the invention will appear better on reading the following description of an embodiment of the invention given by way of nonlimiting example. The description refers to the appended figures in which:

- Figure la already described shows a flexible intraocular implant of known type; - Figure lb already described illustrates the mode of folding and insertion of the implant of Figure la in the eye;

- Figure 2a is a front view of a flexible implant according to the invention;

- Figure 2b is a side view of the implant of Figure 2a; and - Figure 3 is a schematic side view of the implant showing the method of geometric definition of the fastening elements of the haptic part of the implant.

Referring first to Figures 2a and 2b, we will describe the general shape of the flexible one-piece implant. The implant is constituted by a substantially circular optical part 50 and by a haptic part constituted by two fixing elements 52 and 54 arranged substantially diametrically opposite with respect to the optical part 50. We will call O the center of the optical part, XX 'the axis of symmetry of the implant along the direction of the fastening elements 52, 54 and YY' the second axis of symmetry of the implant. Finally, the axis of revolution of the optical part of the implant 50 will be called ZZ ′. The two fixing elements 52 and 54 being identical, the fixing part 52 will only be described in detail. The implant is preferably made in hydrogel. This consists of a contact portion 56 having the general shape of an arc of a circle with center O and diameter DI. The cord C which supports the fixing portion 56 has a length substantially equal to the diameter D of the optical part. The edge 56a of the contact portion is rounded in cross section. The contact portion 56 is connected to the periphery 50a of the optical part by two assemblies in the form of a non-perforated veil 58 which therefore extend from the periphery 50a of the optical part to the contact portion 56. This veil is limited by two edges respectively 60 and 62 which each have the shape of a curve having a regular curvature. More precisely, each curve defining an overhang 60, 62 is preferably connected tangentially to the periphery 50a of the optical part and it is connected by a bent portion 64 to the contact portion 56. The variable radius of curvature of the edges 60, 62 is such that, between the contact portion and the periphery of the optical part, the length 1 between two points PI and P2, edges of one of the webs 58 is less than the diameter D of the optical part. Preferably also, the angle at the center a corresponding to the two points P'1 and P'2 for connection to the periphery 50a of the optical part is less than 180 degrees but greater than 90 degrees. This angle can advantageously be between 110 and 130 degrees. As best shown in Figure 2b, each web 58 has a thickness which decreases from the contact portion 56 to the periphery 50a of the optical part. In addition, it can be seen that this figure shows that the diameter D2 of the circle limiting the front diopter 70 in the form of a spherical cap is less than the diameter D3 of the posterior diopter 72 also in the form of a spherical cap. This difference in diameter makes it possible, thanks to a larger diameter D3, for the posterior diopter, to ensure good contact between the posterior wall of the capsular bag while reducing the thickness e of the optical part along its axis of revolution ZZ ' . Preferably, D2 is 5.5mm and D3 is 6mm. In addition, the diameter of the haptic DI is equal to 11mm. The thickness E 1 of the contact portion 56 is between 0.4 and 0.5 mm while the thickness E 2 of the web in its zone of connection to the optical part is of the order of 0.2 to 0.25 mm . Referring now to FIG. 3, a description will be given of the mode of definition of the shape of the fastening elements 52 and 54 (anterior face in the case of FIG. 3) is arranged on a portion of toric surface T represented by dotted lines on Figure 3. This tare portion is defined by the rotation of a circle with center 0 'and radius RI around the optical axis ZZ' of the implant. During this rotation, the center 0 'describes a circle of diameter D4 this circle being centered on the axis ZZ' and arranged in a plane orthogonal to this axis. Preferably, the radius RI is between 5 and 30mm and the diameter D3 is between 5 and 30mm. It should be added that the invention exploits only the flexibility and pliability properties of the hydrogel and not its properties. hydrophilic. The implant according to the invention could therefore equally well be made of another flexible material such as silicone which is also well known for the production of intraocular implants.

Claims

1. One-piece intraocular implant made of a flexible material and comprising a substantially circular optical part (50) and a haptic part consisting of two fixing elements (52, 54) diametrically opposite with respect to said optical part, each fixing element comprising a contact portion (56) intended to come into contact with the internal wall of the eye and connection means (58) for connecting said contact portion to the periphery of said optical part, said contact portions having the form of an arc having a substantially the same center as the optical part, characterized in that the cord (C) supporting each contact portion (56) has a length substantially equal to the diameter (D) of the optical part, in that that each of the connection means (58) has the form of a non-perforated veil extending between said contact portion and the periphery of said optical part, said veil being limited by bo rds (60, 62) having the shape of a curve with regular curvature, each curve extending between one end of the contact portion and a point on the periphery of the optical part, the two points of the edges of the veil located on the same perpendicular to the axis of symmetry (XX ') of the implant in the direction of the fastening elements being separated by a distance less than the diameter of said optical part.

2. Implant according to claim 1, characterized in that said optical part (50) is limited by two respectively anterior (70) and posterior surfaces in the form of spherical caps each bounded by a circle, the circle of the anterior surface having a diameter (D2) lower than that (D3) of the posterior surface.

3. Implant according to claim 2, characterized in that the diameter of the circle of the posterior surface is of the order of 6mm and in that the diameter of the circle of the anterior surface is of the order of 5.5mm.

4. Implant according to any one of claims 1 to 3, characterized in that one of the faces of the fastening elements (52, 54) of the haptic part is defined by a portion of toric surface (T) having as axis the axis of revolution of said optical part.

5. Implant according to any one of claims 1 to 4, characterized in that each fixing element (52, 54) has a thickness, according to the direction of the axis of revolution of the optical part, which decreases by the contact portion (56) towards the periphery

(50a) of the optical part.

6. Implant according to any one of claims 1 to 5, characterized in that it is made of hydrogel.

7. Implant according to any one of claims 1 to 5, characterized in that it is made of silicone.

8. Implant according to any one of claims 1 to 7, characterized in that the diameter (DI) of the contact portions is of the order of 11mm.