WO1999002106A1 - Flexible single-piece intraocular implant - Google Patents

Abstract

The invention concerns a flexible single-piece intraocular implant made from a supple material comprising a substantially circular optical part (10) and a haptic part, characterised in that said haptic part consists of two haptic assemblies (12, 14) arranged substantially symmetrical relative to the optical part diameter, each haptic assembly consisting of: two haptic members (16, 18) capable of elastic deformation each comprising a first end (16a, 18a) integral with the optical part periphery and a second end (16b, 18b) designed to be urged in contact with the eye internal wall, said haptic members forming between them an angle of less than 100 DEG at the centre; and a linking element (20) with two ends, each end being connected to one of the haptic members, said linking element having no link with the optical part and no contact with the eye internal wall when said implant is set in the eye.

Description

 Flexible monobloc intraocular implant.

The present invention relates to a flexible monobloc intraocular implant. We know that intraocular implants can be classified into two main categories depending on the nature of the material with which they are made. On the one hand, there are rigid intraocular implants which are produced most often using PMMA and in which the elasticity of the haptic part is obtained by giving it a shape allowing its elastic deformation. On the other hand, a distinction is made between so-called flexible intraocular implants which are manufactured with a material which is most often a hydrophilic acrylic or a silicone-based compound.

As is also well known, the advantage of flexible intraocular implants is that, for their introduction into the eye, the optical part which is itself flexible can be folded, which allows implantation in the eye of the system through a reduced corneal incision.

With regard to the technique for placing flexible intraocular implants in the eye, two main methods can be distinguished. On the one hand, there is a manual technique which consists in a first step of folding the intraocular implant and in particular its optical part and of maintaining with the aid of pliers the optical part in its folded state and of introducing the implant folded through the incision inside the eye. A second implantation process consists in using an injector. This device comprises a first folding zone in which the optical part and the haptic part of the implant are folded in particular using a piston and an insertion part of tubular shape with a reduced diameter in which the implant previously folded is maintained in this folded form for introduction into the interior of the eye.

With regard to the haptic part of flexible intraocular implants, there are also two main embodiments. On the one hand, there are the so-called shuttle-shaped implants in which the haptic part consists of two diametrically opposite elements of relatively large size and the free end of which rests on the internal wall of the eye in an arc of long circle. Due to the conformation of the haptic part, these implants lend themselves well to placement using an injector since the haptic part is folded at the same time as the optical part. However, they often have the disadvantage of causing an arch effect when they are placed in the eye, which risks causing an axial displacement of the optical part over time. The other type of haptic part in the form of a handle or in the form of a haptic element having a reduced length support on the wall of the eye, this avoids the effect of arch, but this form of haptic part is poorly suitable for the use of an injector because of the great difficulty in correctly folding the haptic part at the same time as the optical part.

An object of the present invention is to provide a flexible monobloc intraocular implant having a haptic part whose areas of contact with the internal wall of the eye are multiple but reduced and which, however, is well suited to the use of a injector for its placement in the eye.

To achieve this object according to the invention, the monobloc intraocular implant made of flexible material comprising a substantially circular optical part and a haptic part is characterized in that said haptic part consists of two haptic assemblies disposed substantially symmetrically with respect to a diameter of the optical part, each haptic assembly consisting of:

- two elastically deformable haptic members each comprising a first end secured to the periphery of the optical part and a second end intended to come into contact with the internal wall of the eye, said haptic members forming an angle between them less than 100 degrees ; and

a connecting element having two ends, each end being connected to one of the haptic members, said connecting element having no connection with the optical part and not being in contact with the internal wall of the eye when said implant is placed in the eye.

It is understood that, thanks to the presence of the connecting element in each haptic assembly, it will be possible to conveniently obtain, when using the injector, the folding of the haptic part at the same time as the folding of the optical part since the injector piston cooperates with these connecting elements.

According to a preferred embodiment, each haptic member comprises a solid arm comprising at its second end a recessed portion surrounded by a rim comprising an elastically deformable contact portion. 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 non-limiting example. The description refers to the appended figures, in which: - Figure 1 is a front view of a flexible monobloc intraocular implant according to the invention;

- Figure 2 is a side view of the implant of Figure 1;

- Figure 3 is a front view of the intraocular implant of Figure 1 after its placement in a capsular bag having a first diameter Dl; and

- Figure 4 is a view similar to that of Figure 3 in the case where the diameter of the capsular bag D2 is less than the diameter Dl.

Referring first to Figures 1 and 2, we will describe a preferred embodiment of the flexible intraocular implant in one piece. As shown in FIG. 1, the intraocular implant comprises an optical part 10 which is substantially circular and whose diameter in this embodiment is equal to 6 mm. The intraocular implant also comprises two haptic assemblies respectively referenced 12 and 14 which are connected to the periphery 10a of the optical part and which are arranged symmetrically with respect to a diameter X, X ¹ of the optical part 10. The two haptic assemblies 12 and 14 being identical, we will simply describe the haptic assembly 12. This is essentially constituted by two haptic organs 16 and 18, each haptic organ having a first end 16a, 18a connected to the periphery 10a of the optical part and a second end 16b, 18b elastically deformable and intended to come into contact with the internal wall of the eye when the implant is placed in the eye. The haptic assembly 12 also includes a connecting element 20 which connects the haptic members 16 and 18. The haptic members 16 and 18 are arranged substantially symmetrically with respect to the diameter Y, Y 'of the optical part, this diameter Y, Y' being orthogonal to the diameter X, X '. As shown in Figure 1, each haptic member 16 or 18 comprises a recessed portion 22 which is surrounded on its major part by an elastically deformable rim 24 which thus constitutes the ends 16b and 18b. Each haptic member 16 or 18 also comprises a solid arm 26, one end of which constitutes the end 16a, 18a of the haptic member and the other end of which 26a is connected to the flange 24 and at the same time forms part of the periphery of the recess 22. The outer edge of each arm 26 is tangentially connected to the periphery of the optical part.

As shown in Figure 1, the connecting element 20 is in fact connected in the end region 26a of the arms 26 of the haptic members. This connection zone referenced 28 therefore constitutes a relatively massive part with the ends 26a of the arms 26. It can also be seen that the connecting element 20 has no contact with the periphery 10a of the optical part, the connecting element 20 defining with the arms 26 and the periphery of the optical part an opening 30. It can also be seen that, in the same haptic assembly, if we consider the points of contact of the ends 18b and 16b of the haptic organs, the rays joining these contact points at the center O of the optical part make an angle at the center a which is of the order of 60 °. More generally, this angle at the center a is preferably between 30 and 100 ° and more preferably between 45 and 75 degrees.

The holding in place of the intraocular implant inside the eye is ensured by an elastic force developed by the deformation of the edges 24 of the hollowed-out ends of the haptic organs. To promote this deformation, the width e of the flanges is of the order of 0.15 mm, while, as best shown in FIG. 2, the thickness h in a direction orthogonal to the optical plane of the implant is l '' order of 0.37 mm. More generally, the thickness h is at least equal to 1.5 times the width 1 and more preferably at least equal to twice this width. It can also be seen in this figure that, near the periphery 10a of the optical part, the haptic members have a thickness h 'of the order of 0.25 mm and that, at rest, the ends of the haptic members are arranged on a circle with diameter D '. The diameter D 'is adapted to the dimensions of the capsular bag, in which the implant must be placed. In the example considered, the diameter D 'is equal to 11.25 mm. FIG. 2 shows that the median plane of the haptic assemblies coincides with the optical plane of the optical part 10. In addition, it can be understood that the thickness of each haptic member increases from the periphery of the optical part towards the end free from the organ. Figures 3 and 4 show the deformation of the ends of the haptic organs when the implant is placed in the capsular bag. In the case of FIG. 3, the diameter of the capsular bag D1 is 10.5 mm, while in the case of FIG. 4, the diameter of the capsular bag D2 is 10 mm. It is important to note that the connecting elements 20 are configured in such a way that, when the implant is placed in the eye, the connecting elements are not in contact with the inner wall of the eye. This contact only occurs at the ends of the haptic organs.

It is clear from these Figures 3 and 4 that the elastic effect is obtained by the deformation of the rim 24 of the four haptic members. The elastic force thus develops substantially along radii of the optical part and concerns only a relatively limited zone Z1 of the internal wall of the eye. These efforts are developed in the optical part. However, due to each defined haptic set, two contact zones Zl, very good stability of the implant is obtained after it has been placed in the eye while avoiding the arch effect most often encountered with implants. flexible monoblock intraoculars of the "shuttle" type.

Preferably, the flexible material used to make the one-piece implant is a crosslinked copolymer of hydroxylethyl methacrylate (HEMA) and ethyl methacrylate (EMA). Such a material has an average modulus of elasticity of the order of 0.78 MPa slightly higher than that of a HEMA poly. It should also be added that the invention would not be departed from if the haptic organs had a different configuration. They must be able to develop the elastic effect required when the implant is placed in the eye and that the two haptic organs of the same haptic assembly are connected by a band or connecting element.

Claims

1. One-piece intraocular implant made of flexible material comprising an optical part (10) substantially circular and a haptic part, characterized in that said haptic part consists of two haptic assemblies (12, 14) arranged substantially symmetrically with respect to a diameter of the optical part, each haptic assembly consisting of: - two elastically deformable haptic members (16, 18) each comprising a first end (16a, 18a) secured to the periphery of the optical part and a second end (16b, 18b) intended to come into contact with the internal wall of the eye, said haptic organs forming between them an angle at the center less than 100 degrees; and - a connecting element (20) having two ends, each end being connected to one of the haptic members, said connecting element having no connection with the optical part and not being in contact with the internal wall of the eye when said implant is placed in the eye. 2. Intraocular implant according to claim 1, characterized in that each haptic organ (16, 18) comprises a solid arm which has at its second end a recessed portion (22) surrounded by a flange (24) comprising an elastically contact portion deformable. 3. Intraocular implant according to claim 2, characterized in that a part of said flange (24) is connected to the periphery of the optical part by an arm (26) whose width in the optical plane is much greater than that of the contact portion of the rim. 4. Intraocular implant according to claim 3, characterized in that each end of the connecting element (20) is connected to the arm (26) of one of the haptic organs (16, 18), whereby an opening (30) is formed between the periphery of the optical part (10) and the connecting element and the two arms of the same haptic assembly. 5. Intraocular implant according to claim 4, characterized in that the ends of the connecting element (20) are connected to the arms (26) near the end of said arms which partially surrounds said recess (22). 6. intraocular implant according to any one of claims 2 to 5, characterized in that the contact portion has a thickness (h) according to the direction of the optical axis of the implant greater than or equal to 1.5 times the width (1) of the contact portion.