TREATMENT TO IMPROVE ADHESIVE PROPERTIES OF CORNEAL IMPLANT

Abstract

A method is described of improving adhesion of an ocular implant to corneal tissue by forming an implant adhesive layer on the ocular implant, the implant adhesive layer having greater adhesive strength than a rest of the implant or by forming a corneal adhesive layer on a posterior surface of a posterior portion of the corneal tissue, the corneal adhesive layer having greater adhesive strength than a rest of the corneal tissue.

Claims

1-26. (canceled)

27. An ocular device comprising: a corneal copolymer implant made of a polymeric material and comprising a surface having micro-porosity for forming adhesion with corneal tissue, and wherein said implant comprises a barrier to water.

28. The ocular device according to claim 27, wherein said implant has a dome shape.

29. The ocular device according to claim 27, wherein said implant comprises a member selected from the group consisting of hyaluronic acid, and the potassium and sodium salts thereof.

30. The ocular device according to claim 27, wherein said implant comprises pockets, depressions or protrusions on said surface.

31. The ocular device according to claim 27, wherein said polymeric material comprises a partially hydrolyzed polymeric material.

32. The ocular device according to claim 27, wherein said polymeric material comprises a methacrylic polymer.

33. The ocular device according to claim 27, wherein said polymeric material comprises a hydroxyethyl methacrylate.

34. The ocular device according to claim 27, wherein said polymeric material comprises a methylmethacrylate.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0008] The present invention will be understood and appreciated more fully from the following detailed description taken in conjunction with the drawings in which:

[0009] FIGS. 1 and 2 are simplified illustrations, respectively in coronal and transverse planes, of a corneal implant, constructed and operative in accordance with an embodiment of the present invention; and

[0010] FIGS. 3A and 3B are simplified anterior and side view illustrations of the corneal implant.

DETAILED DESCRIPTION OF EMBODIMENTS

[0011] Reference is now made to FIGS. 1 and 2, which illustrate a corneal implant 10, constructed and operative in accordance with an embodiment of the present invention. The implant 10 may be a hydrophobic pseudo-endothelial implant, which can be used instead of an implant from a donor in a DSEK (Descemet Stripping Endothelial Keratoplasty) or DMEK (Descemet Membrane Endothelial Keratoplasty) surgery. Implant 10 serves as a water barrier enabling the dehydration of the cornea.

[0012] Implant 10 may be constructed of a clear, transparent, biologically compatible material, such as but not limited to, polymethylmethacrylate (PMMA), silicone, silicone rubber, collagen, hyaluronic acid (including the sodium, potassium and other salts thereof), hydrogel, such as acrylic or methacrylic hydrogels, e.g., hydroxyethyl methacrylate or methacrylic acid copolymer/partially hydrolyzed poly(2-hydroxyethyl methacrylate) (known as PolyHEMA), polysulfones, thermolabile materials and other relatively hard or relatively soft and flexible biologically inert optical materials, or any combination of such materials, such as a gel encapsulated in a polymer. Implant 10 may thus be rigid, semi-rigid or foldable, for example.

[0013] As seen in FIGS. 3A and 3B, the corneal implant 10 is dome-shaped with an anterior surface 13 and a posterior surface 15 (anterior and posterior defined to correspond to the anterior-posterior axis 11 of the eye). Pockets, depressions or protrusions 17 may be formed on anterior surface 13 or posterior surface 15 to assist in proper positioning of the implant 10.

[0014] Prior to bonding implant 10 to the posterior portion of the cornea, as in PLK (posterior lamellar keratoplasty) or DSEK, a thin posterior or lenticule of stromal tissue (along with Descemet's membrane and endothelial cells attached) may be removed from the cornea of the patient's eye. Alternatively, as in Descemet's strip endokeratoplasty, only the Descemet's membrane and endothelial cells are removed. Alternatively, the implant may be attached to the endothelium of the cornea without any posterior surface striping.

[0015] In one embodiment, implant 10 is bonded to the posterior portion of the cornea 12 by means of an implant adhesive layer 14 formed on the anterior surface of implant 10. In another embodiment, implant 10 is bonded to the posterior portion of the cornea 12 by means of a corneal adhesive layer 16 formed on the posterior surface of the posterior portion of the cornea 12. In yet another embodiment, implant 10 is bonded to the posterior portion of the cornea 12 by means of adhesive layer 14 formed on the anterior surface of implant 10 and by means of adhesive layer 16 formed on the posterior surface of the posterior portion of the cornea 12.

[0016] Without being bound to any particular theory, adhesion is the tendency of dissimilar surfaces to stick to one another. Adhesion is either measured in terms of work of adhesion (J/m.sup.2), which is the energy required to separate 1 square meter of joined materials, or it can be measured as peel force (N/m), which is the force required to pull off a strip of material that is 1 meter wide. It is noted that the work of adhesion is independent of and not proportional to the surface tension. Surface tension plays only a minor role in the adhesion of the two joined materials, but surface tension and wetting may be important for initiating adhesion.

[0017] There are different adhesive forces:

[0018] 1. Mechanical adhesion: the adhesive flows into openings or pores of the substrate and interlocks with the micro-porosity of the substrate.

[0019] 2. Electrostatic adhesion: an electrical double layer is formed when two materials come in contact and exchange electrons. This creates an attractive electrostatic or Coulomb force between the two materials.

[0020] 3. Specific adhesion: atoms/molecules of two adhering surfaces form specific bonds such as hydrogen bonds.

[0021] 4. Chemical adhesion: atoms/molecules of two adhering materials form chemical bonds that can be of ionic or covalent character.

[0022] Adhesive layer 14 may be created by making chemical and/or physical changes on the anterior surface of implant 10 that make the layer 14 more adhesive than the rest of implant 10, such as by creating electrostatic, specific or chemical adhesion between the adhesive layer 14 and the corneal tissue. Similarly, adhesive layer 16 may be created by making chemical and/or physical changes on the posterior surface of the posterior portion of the cornea 12 that make the layer 16 more adhesive than the rest of cornea 12, such as by creating electrostatic, specific or chemical adhesion between the adhesive layer 16 and the implant 10.

[0023] For example, by application of laser energy or by applying chemicals or heat treatment on the anterior surface of implant 10 may create chemical changes in the polymer of the implant 10 (e.g., creating covalent bonds) which increase the adhesion of layer 14. As another example, making chemical and/or physical changes on the posterior surface of the posterior portion of the cornea 12 with a femtosecond laser (e.g., passively mode-locked solid state bulk lasers, diode-pumped lasers, titanium sapphire lasers, ultrafast fiber lasers and others) Nd:YAG (neodymium-doped yttrium aluminum garnet) laser, Yb:KGW (ytterbium-doped potassium gadolinium tungstate) laser or Yb:KYW (ytterbium-doped potassium yttrium tungstate) laser and other lasers (pulsed or continuous) that make the layer 16 more adhesive than the rest of cornea 12.

[0024] Plasma treatment may be used to increase the adhesion of the implant by creating adhesive layer 14. In plasma treatment, high voltage discharges are created in an air gap, causing free electrons, which are always present in the air, to accelerate and ionize the gases in the air gap. When the electric discharge is very strong, collisions of high velocity electrons with molecules of gas result in no loss in momentum, and electron avalanching occurs. When the implant 10 (made of a plastic, for example, PMMA) is placed in the discharge path, the electrons generated in the discharge impact the surface of the implant with energies that break the molecular bonds on the impact surface (which becomes layer 14). This impact creates very reactive free radicals, which in the presence of oxygen, can react rapidly to form various chemical functional groups on the surface of the implant (layer 14) that increase surface energy and adhesive capability.

[0025] Corona treatment may be used to increase the adhesion of the implant by creating adhesive layer 14. During corona discharge treatment, electrons are accelerated into the surface of the implant causing long chains to rupture, producing a multiplicity of open ends and free valences are formed, which increases surface energy and adhesive capability. The corona only changes the top molecule chains, which is 0.00001 micron thick.

[0026] Flame treatment may be used to increase the adhesion of the implant by creating adhesive layer 14. By rapidly applying intense heat to the surface of implant 10, molecular chains are broken and polar functional groups are added. Flame treatment also burns off dust, fibers, oils, and other surface contaminates.

[0027] The increase adhesion of layer 14 and/or 16 helps create a bond between the implant and the corneal tissue without the need for application of an external adhesive substance.

[0028] The following table presents a list of possible treatments for creating the adhesive layer to bond the implant 10 to the posterior portion of the cornea 12. Some of the treatments are listed in the table as being used with an added adhesive material, but it is contemplated that adhesion may be enhance even without the added adhesive material.

TABLE-US-00001 TREATMENT MATERIAL PLASMA (AIR) — PLASMA (O.sub.2) NIPAM (N-isopropylacrylamide) Allylamine Allyl alcohol Acrylic Acid PLASMA (O.sub.2/CO.sub.2) EDC + Collagen EDC + Polylisine + star-PEG PLASMA (AR + O2) Vinyl alcohol pp-HMDSO E-BEAM NIPAM UV POLYMERIZATION NIPAM Polyglycidyl ether LASER — ATOMIC DIFFUSION — BONDING SPIN COATING NIPAM — Cyanoacrylate — Amino acid DOPA FREE RADICAL NIPAM POLYMERIZATION