Intraocular non-perforating intra-scleral modular support system

Abstract

An intraocular support system is provided. This apparatus provides support when natural support structures are absent, diminished, or damaged. The apparatus may include a base that inserts into the internal scleral wall in the sulcus in an arched fashion that does not perforate the external scleral wall. It may be self-retaining with barb protrusions. It may include stabilizers that rest on the ciliary body. The base may include a modular junction that allows interchangeable extensions. The extensions may provide varied functions including intraocular lens support, capsular bag support, and accommodation. It may be applied in acute surgical conditions or in planned cases.

Claims

1. An intraocular support apparatus comprising: a base platform and modular extensions.

2. The intraocular support apparatus of claim 1, further comprising a base platform wherein in it involves a stalk with 3 components: Insertion arms, a stabilizer, and a modular junction.

3. The intraocular support apparatus of claim 2, further comprising insertion arms wherein they are arched allowing increased scleral entry without perforation of the outer scleral wall.

4. The intraocular support apparatus of claim 3, further comprising insertion arms wherein there are barb protrusions supporting retention in tissue.

5. The intraocular support apparatus of claim 2, further comprising a stabilizer wherein it rests in the sulcus on the ciliary body promoting stability.

6. The intraocular support apparatus of claim 2, further comprising a stabilizer wherein it rests in the sulcus on the ciliary body providing accommodation.

7. The intraocular support apparatus of claim 2, further comprising a modular junction wherein it provides attachment of extensions.

8. The intraocular support apparatus of claim 1, further comprising extensions wherein there are varied shapes, styles, and functions.

9. A method of attaching the apparatus of claim 3 intraocularly to the globe wherein the arched insertion arms enter the internal scleral wall, traverse in a curved fashion allowing greater tissue penetration, and avoid perforation of the outer scleral wall.

10. A method of attaching the apparatus of claim 4 intraocularly to the globe, further comprising barb protrusions on the arched arms that prevent retraction.

11. A method of stabilizing the apparatus of claim 6 intraocularly wherein the insertion arms and stabilizer prevent movement along a dimensional axis.

12. A method of achieving accommodation wherein stabilizers of claim 6 that rest in the sulcus on the ciliary body amplify and transmit accommodative force to an intraocular lens.

13. A method of attaching modular extensions of claim 7 wherein extensions of varied functions attach to the base at a modular junction.

14. A method of utilizing extensions of claim 8 wherein they are varied in but not limited to size, shape, materials, and functions.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0010] FIG. 1 is a perspective of the present invention illustrating the base platform;

[0011] FIG. 2 is a perspective of the present invention illustrating an example of an extension;

[0012] FIG. 3 is a section view of the present invention, illustrating the placement of the arched insertion tips into the sclera without perforation of the outer wall.

DETAILED DESCRIPTION OF THE INVENTION

[0013] The following is a detailed description of the best currently contemplated modes of carrying out exemplary embodiments of the invention. The description is not to be taken in a limiting sense, but is made merely for the purpose of illustrating the general principles of the invention.

[0014] The present apparatus includes a base platform and modular extensions as referenced in FIG. 1 and FIG. 2. In FIG. 1 the base platform involves a stalk 4 with three components: Insertion arms 1, a stabilizer 3, and a modular junction 5.

[0015] Insertion arms include barb protrusions 2 that prevent retraction. Multiple barbs assist retention unlike single flange or single knot with sutures or haptics. As referenced in FIG. 3, the distal sharp arched tips 10 are curved outward to allow internal scleral wall 8 entry and internal tissue 9 engagement without perforating the outer scleral wall 11. This results in greater insertion length with curved entry relative to straight entry with sutures. Additional arms can be employed as needed for increased support force. T base platform can be attached to the internal scleral wall with forceps or specialized equipment to inject it into the sulcus above the ciliary body from any angle. This apparatus allows ease and speed of insertion by following the iris plane until scleral engagement. Multiple devices can be placed in multiple quadrants for additional support. This device avoids sutures, intraocular lens haptic externalization, scleral perforation and their potential complications.

[0016] The insert rests in the sulcus between the ciliary body and iris. The stabilizer 12 in FIG. 3 rests in the sulcus on the ciliary body. Stabilizers along with the insertion arms prevent any unwanted movement in the x, y, or z axis. The stabilizers could be thick or thin, loops, or solid shapes. A sphere or ellipsoid, separately or combined, could provide gentle stability. Rounded contour protects adjacent structures.

[0017] The modular junction 5 in FIG. 1 allows interchangeable extensions to attach into the insertion base at this junction. As referenced in FIG. 2 the extension 7 has a junction 6 to attach to the base. Placement of extensions into the junction is adjustable allowing titration of force. Modular extensions can create a multifunctional system that can include zonule replacement, capsule support, partial or complete intraocular lens support, hook for dislocated intraocular lens, and flexibility for future options. Variations of these examples could also exist. A smaller size support could be employed if only a single sector of the capsule needs support. Small support bars could be utilized for added support with larger implants if needed. Loops could be used to fixate a dislocated intraocular lens. Lens support alone could be another variation.

[0018] The device includes an accommodation function. This device rests in the sulcus on the ciliary body. As the ciliary body contracts and relaxes, some force is transmitted to the stabilizers. This force can be amplified by modifying the width and shape of the stabilizers to maximize transmission of ciliary muscle contraction force. This force is transmitted through an extension that rests under the intraocular lens, acting as a lever, further amplifying muscle force and providing accommodation. A modified version with inferior lens support that could slip under an existing intraocular lens could provide accommodation to existing pseudophakic patients. An ellipsoid stabilizer could smoothly amplify reactions from the ciliary body. An extended stabilizer could maximize amplification of existing accommodative function. This device can bypass zonular laxity and lens stiffness components of accommodation loss. It enhances natural accommodation. It can be used with any posterior chamber intraocular lens. It can be used with a previously implanted posterior chamber intraocular lens. No visual distortion or halos would occur.

[0019] This device can be manufactured with materials that are malleable and biocompatible. Implant material would be flexible with memory. This allows for long term placement and allows constriction in order to insert through a small corneal opening and expands once intraocular. Different sizes, styles, and shapes of the various components can be used for different functions. The above can also be modified and reconfigured to create the same or similar functions.

[0020] While exemplary embodiments have been described and illustrated, these should not be construed as limitations on the scope of what is claimed or on what may be claimed. Various modifications and enhancements can be made without departing from the spirit and scope of the invention.