FR2675991A1 - Intraocular implant - Google Patents

Abstract

Intraocular implant comprising an optic part (1) forming a lens (2), and a haptic part (3) supporting the optic part in the eye, comprising two loops (4), (5) which are asymmetrical with respect to the axis (6) of rotation formed by the optic axis of the lens, each loop extending along a continuous curve turned towards the optic centre (6) of the lens, moving away gradually from the optic part, starting from a connection zone (4a, 5a) adjacent to the optic part, as far as a free end (4b, 5b) situated at a distance from the said optic part, characterised in that, on the one hand, the angular distance with respect to the optic centre (6) of the lens, measured along the smaller angle, between the starting point (4c) of a first loop (4) on the optic part (1), and the end point (5d) of the second loop (5), at a distance from the optic part, is almost 0 DEG , and, on the other hand, the angular distance (7), measured along the smaller angle, between the two end points (4d, 5d) of the two loops (4, 5), respectively, is between 140 and 150 DEG , the developed length of the two loops (4, 5), measured in each case from its starting point (4c, 5c) to its end point (4d, 5d), being substantially equal.

Description

INTRA # CULAR IMPLANT
The present invention relates to an intraocular implant or lens, intended to focus the light rays received by the eye on its retina, and replacing the lens when its refraction is defective.

During a surgical procedure, such an implant is placed in the eyeball, in its posterior chamber, preferably in the capsular bag.

 Various types of implants have already been proposed to date.

The invention relates more specifically to implants comprising
an optical part forming a lens, and a haptic part, integral or not with the optical part, supporting the latter in the eye. This haptic part includes two asymmetrical handles relative to the optical axis of the lens, considered as an axis of rotational symmetry.

Each flexible loop extends along a continuous curve, with a radius of curvature varying along its length, turned towards the optical center of the lens, progressively moving away from the optical part, and this from a connection zone adjacent to the part. optical, to a free end located at a distance from said optical part.

For such an implant, two often opposite constraints must be satisfied
- on the one hand, the haptic part must provide support and good centering of the optical part in the eye, once the implant has been inserted and placed in the latter; in practice, this involves two elastic handles,
arranged on either side of the optical part, relatively long to each take support against the wall of the eye
- on the other hand, the size of the haptic part, outside the eye, must be as limited as possible, to allow introduction of the implant, practically without effort exerted on the eye, by an incision corneal or scleral as small as possible; in practice, this involves handles each having a gathered shape.

 As we can see, the two constraints of optical performance in the eye, and the easy and least penalizing implantation in the eye, are difficult to reconcile.

 The present invention relates to a haptic allowing to better reconcile the two constraints explained above.

 According to the present invention, on the one hand the angular distance from the optical center of the lens, measured at the smallest angle, between the starting point of a first loop on the optical part, and the end point of the second handle, at a distance from the optical part, is close to 0, and on the other hand the angular distance, always measured at the smallest angle and relative to the optical center of the lens, between the two extreme points of the two handles respectively, is between 1400 and 1500. And the developed length of the two handles, measured for each of its starting point at its extreme point, is substantially equal.

 As the description below will establish, it has in fact been determined that such geometrical and dimensional characteristics of the haptic part allow, by a single gesture of the surgeon, to effect four elementary displacements ensuring in total an easy introduction and effortlessly of the implant in the eye, and this resulting in correct centering of the implant in the eye.

The present invention is now described with reference to the accompanying drawings, in which
- Figure 1 shows a front view of an implant according to a first embodiment of the invention
- Figure 2 shows a front view of an implant according to a second embodiment of the invention
- Figures 3 to 6 show in decomposed form, respectively the four movements that can be accomplished by the ophthalmologist surgeon, in one and the same gesture, during the introduction of an implant according to the invention in the capsular bag of the eye.

An implant traditionally includes
an optical part 1 of generally circular profile comprising or forming a lens 2, having any shape suitable for the desired optical correction, for example bi-convex, bi-concave, meniscus, etc.

 a haptic part 3 supporting the optical part 1 in the eye, comprising two handles 4 and 5, asymmetrical with respect to the axis 6 of rotation constituted by the optical axis of the lens, and arranged around the periphery of the part optic 1, according to an overall profile circumscribing the latter at a distance.

 Each loop 4 or 5 extends along a continuous curve turned towards the optical center 6 of the lens, and gradually moving away from the optical part 1, from a connection zone 4a or Sa, adjacent to the optical part 1, up to 'at a free end 4b or 5b, located at a distance from this same optical part 1.

In a manner known per se, handles 4 and 5 can be obtained
or produced, in a single piece with the optical part 1, or constitute separate parts, attached or mounted on the latter. Also, in a manner known per se, the free ends 4b and 5b can be arranged in the same plane as the optical part 1, or in a plane parallel to the latter, situated anteriorly or posteriorly with respect to the plane of the lens, with respect to to the morphology of the eye.

 According to the present invention, the following geometric and dimensional characteristics are implemented.

 The angular distance from the optical center 6 of the lens, measured at the smallest angle between the starting point 4c of a first loop 4 on the optical part 1, and the extreme point 5d of the second loop 5, at a distance of the optical part 1, is close to or equal to 00. The angular distance 8, measured at the smallest angle, between the starting point 5c of the second loop 5 on the optical part 1, and the extreme point 4d of the first handle 4, at a distance from the optical part, is between 60 and 700.

 The angular distance 7, measured at the smallest angle, always with respect to the optical center 6, between the two extreme points 4d and 5d of the two handles 4 and 5 respectively, is between 140 and 1500.

 Finally, the developed length of the two handles 4 and 5, measured for each of its starting point 4c or 5c, at its extreme point 4d or 5d, is substantially equal.

In order to facilitate the handling of such an implant, the free end 5b of the second loop 5 is provided with a through hole 5e, to allow the implant to be placed in the eye. Preferably,
the through hole 5e located on the second loop 5 is disposed opposite the starting point 5c of the same loop on the optical part 2, relative to the optical center 6. In this way, when the implant is inserted into the eye, as shown in Figure 3, the developed length of the first loop 4, between its starting point 4c and its fulcrum on the inner wall of the eye, is smaller than the developed length of the second handle, between the through hole 5e and its starting point 5c. It is this dimensional characteristic which favors the tilting shown in Figure 4, and explained below.

 There may also be through holes 4e and 5e on the connection zones 4a and Sa of the handles 4 and 5 respectively.

In accordance with Figures 3 to 6, there is shown the introduction of the implant previously described in the capsular bag 10 of the eye, of generally circular shape, by a diametral incision 10a, made
in this last. In the positions shown in Figures 3 to 6, the implant
is arranged in the bag 10, two thirds of its length, where it follows that in this position, the handle 4 is almost completely in the bag 10, while the handle 5 is half in the same bag.

By using the through hole 5e, by a single and same gesture, that is to say an upward push slightly oblique, directed towards the free end 4b of the handle 4, one can combine the following four displacements
- according to Figure 3, by operator action directed along the arrows A, compression of the loop 5 to the optical part 1
- According to Figure 4, tilting or pivoting of the optical part 1, around point 15, in the direction of the arrows B ;; as already said, this tilting results from the greater length and therefore resistance of the second loop 5, leading to a tangential thrust along B, exerting a tilting torque around the point 15, this tilting facilitates the crossing of the upper part of the anterior capsule, limiting the force exerted on the capsular bag 10
- according to Figure 5, a dextrorotatory rotation of the optical part 1, in the direction of the arrows C
- according to Figure 6, compression of the loop 4 in the direction of the arrows D.

 The displacements described above are obtained due to the deformations induced in the haptic, by the surgical gesture of the surgeon, these deformations being determined by the geometric and dimensional parameters retained according to the present invention.

 All this results in an effortless and precise insertion of the implant into the capsular bag. This, once placed in the latter, is placed centrally with respect to the optical axis of the eye.

 According to Figure 2, another embodiment of the present invention consists in limiting in part the radial extension of the optical part 2, by stripping it according to the profile shown in dotted lines.

 Thanks to the geometric and dimensional characteristics explained above, the movement of the implant in the eye, when it is inserted into the eyeball, is essentially determined by its shape. As a result, from the same operative gesture, the surgeon masters the placement of the intraocular lens much better, and with better reproducibility.

Claims (4)

 1 / intraocular implant comprising an optical part (1) forming a lens (2), and a haptic part (3) supporting the optical part in the eye, comprising two loops (4) (5) asymmetrical with respect to the axis (6) of rotation constituted by the optical axis of the lens, each handle extending along a continuous curve turned towards the optical center (6) of the lens, progressively moving away from the optical part, from a zone of connection (4a, 5a) adjacent to the optical part, up to a free end (4b, 5b) located at a distance from said optical part, characterized in that on the one hand the angular distance relative to the center (6) lens optic, measured at the smallest angle, between the starting point (4c) of a first loop (4) on the optical part (1), and the end point (5d) of the second loop (5) , at a distance from the optical part, is close to 0, and on the other hand the angular distance (7), measured at the smallest angle, between the two extreme points (4d, 5d) of the two handles (4,5) respectively, is between 140 and 1500, the developed length of the two handles (4,5), measured for each of its starting point (4c, 5c ) at its extreme point (4d, 5d), being substantially equal.  2 / Implant according to claim 1, characterized in that the free end (5b) of the second loop (5) is provided with a hole (5e), to allow its placement in the eye.  3 / Implant according to claim 1, characterized in that the angular distance (8), measured at the smallest angle, between the starting point (5c) of the second loop on the optical part (1), and the end point (4d) of the first handle (4), at a distance from the optical part, is between 60 and 700.  4 / implant according to claim 2, characterized in that the hole (5e) located on the second loop (5) is arranged opposite the starting point (5c) of the same loop on the optical part (2), relative to the optical center (6).