TOROIDAL GLAUCOMA DRAINAGE DEVICE

Abstract

The invention provides an intraocular drainage implant whose drainage capacity is regulated by opening a plurality of laser-sensitive spots. The implant is useful for fine regulation of the eye fluid outflow in handling glaucoma.

Claims

1. An intraocular drainage implant with adjustable drainage capacity, comprising an outer surface impermeable to aqueous fluids with a plurality of laser-sensitive spots permeable to aqueous fluids after laser irradiation.

2. The implant of claim 1, being a glaucoma drainage device.

3. The implant of claim 1, comprising a tubing whose ends are attached to each other by means of a lock to form a closed loop.

4. The implant of claim 1, essentially having a toroidal shape.

5. The implant of claim 1, for implanting in the anterior chamber near the limbus of an eye or at the level of the limbus.

6. The implant of claim 1, comprising a tubing closed in a loop and a neck for fixation suture.

7. The implant of claim 6, having a fixed position near the limbus of an eye or at the level of the limbus, wherein a part of said loop is located within the anterior chamber of said eye at the level of angle, and wherein said neck is sutured to the sclera of said eye.

8. The implant of claim 3, wherein said lock comprises a T-tube connected to a linear tube for shunting eye fluid from said loop to an extraocularly situated plate.

9. The implant of claim 6, comprising a tubing closed in a loop by a T-shaped lock, a linear tube connected to the loop via said lock, and an extraocularly situated plate connected with said linear tube, wherein a part of said loop is located within the anterior chamber of said eye, and wherein said neck and said plate are sutured to the sclera, the plate being either inside the sclera or onto the external surface of the sclera.

10. The implant of claim 6 for draining the eye fluid, wherein a part of said loop is located inside the anterior chamber near the limbus of said eye and a part of said loop is located outside said anterior chamber.

11. The implant of claim 6 with adjustable drainage capacity, comprising an outer surface impermeable to aqueous fluids with a plurality of laser-sensitive spots permeable to aqueous fluids after laser irradiation, wherein said eye fluid enters to said loop part which is located in the anterior chamber, via openings created from at least a part of said plurality of spots, and wherein said fluid is shunted via said loop out of the anterior chamber.

12. The implant of claim 11, being sequentially irradiated by laser in several steps, so that a greater part of said plurality of spots is opened to aqueous fluids after each step, thereby optimizing the volume of fluid to be continually removed from the eye.

13. A glaucoma drainage device for intraocular implanting, comprising a tubing having an outer surface impermeable to aqueous fluids with a plurality of laser-sensitive spots permeable to aqueous fluids after laser irradiation, wherein free ends of the tubing are attached to each other by means of a lock to form a closed loop, the device being implanted in the anterior chamber near the limbus of an eye and being sutured to the sclera to ensure its fixed position, said lock optionally comprising a T-tube to connect said loop with an extraocularly situated plate via an essentially linear connector, wherein a part of said loop is located within the anterior chamber of said eye shunting fluid out of the anterior chamber, the volume of said fluid being affected by the fraction of said spots being converted to openings by said irradiation, the fraction being optimized by sequentially irradiating the device in several increments.

14. A glaucoma drainage device according to claim 13 for use in managing refractory glaucoma.

15. A method of treating refractory glaucoma in an eye in need of such treatment, comprising i) providing an intraocular tubular implant having an outer surface impermeable to aqueous fluids, with a plurality of laser-sensitive spots permeable to aqueous fluids after laser irradiation, the implant having a shape of open tubing optionally having a narrowed site (a neck); ii) implanting said tubular implant in the anterior chamber near the limbus of an eye; iii) attaching the free ends of said tubular implant to each other by means of a lock to form a closed loop, the lock optionally having a T-shape, the loop essentially having a toroidal shape; iv) fixing the position of said loop outside the eye, but under the conjunctiva or scleral flap, by suturing it to the sclera, optionally using said narrowed site (neck), wherein the loop is near the limbus of an eye, its part being located within the anterior chamber; v) if the loop comprises said T-shaped lock, connecting the lock with an extraocularly situated plate via a linear connector, the plate being sutured to the sclera, located either within or outside the sclera; vi) measuring the intraocular pressure (TOP) of said eye; vii) if said TOP is higher than required, irradiating the implanted device by laser whereby opening a part of said plurality of laser-sensitive spots on the surface of the loop; viii) examining whether the step vii resulted in lowering the value of said TOP; and ix) repeating steps vii and viii till the TOP value reached a desired value.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0016] The above and other characteristics and advantages of the invention will be more readily apparent through the following examples, and with reference to the appended drawings, wherein:

[0017] FIG. 1. is a schematic view showing an eye and three devices with an absorption plate and one device without a plate in accordance with embodiments of the invention, and further showing the position of said devices in the eye relatively toward the anterior chamber angle, limbus and the iris;

[0018] FIG. 2. is a schematic view of a toroidal device in accordance with one embodiment of the invention, showing a closed circular tubing comprising an outer impermeable membrane and laser-sensitive spots;

[0019] FIG. 3. is a schematic view of a toroidal device in accordance with one embodiment of the invention, showing a closed circular tubing similar to that one in FIG. 2 connected to a drainage linear tube leading the fluid to an extraocularly situated absorption plate; situated incomprising an outer impermeable membrane and laser-sensitive spots

[0020] FIG. 4. is a schematic view of a toroidal device in accordance with one embodiment of the invention, showing a bagel-shaped device having a part situated within the anterior chamber, and a part situated outside of the eye; the picture shows optional preplaced openings on the extraocular part which drain fluids from anterior chamber outside; and

[0021] FIG. 5. is a schematic view of a toroidal device in accordance with one embodiment of the invention, showing two types of closures; FIG. 5A shows a closed loop tubular device without a linear member leading the fluid to an absorption plate; FIG. 5B shows a closed loop tubular device with a Y-shaped closure for connecting to a linear member leading the fluid to an absorption plate.

DETAILED DESCRIPTION OF THE INVENTION

[0022] An intraocular drainage device has now been designed that enables to adjust the amount of the exiting liquid according to observed intraocular pressure values, so that glaucoma problems may be more easily managed than with known devices. The device has a torus-shaped outer surface comprising an impermeable and laser insensitive membrane on which a plurality of laser-sensitive spots are placed, potentially forming a plurality of exits for the eye fluid after being eventually opened by applying YAG laser lightaccording to the need. The laser-sensitive spots are preformed during manufacturing of the device and exist before implanting the device to the eye. Preferably, one or more devices are placed in the angle area of the eye suffering from glaucoma, near/through the limbus. More spots, preformed on the torus surface, are laser-irradiated, resulting in higher permeability of the toroidal device or devices, providing higher fluid flow. This enables fine regulation of the drainage, as well as of the intraocular pressure. Known laser-insensitive and laser-sensitive materials can be employed in manufacturing devices according to the invention. Only for the sake of example, laser-sensitive polyesters may be mentioned here, but any other suitable material may be employed; in another aspect, the employed polymer may be processed to be thinned on certain areas, for example in chessboard manner. In one embodiment, the size of the spots, from which the liquid-releasing holes are formed, is lower than dimensions of typical contaminating microorganisms. The number of pre-formed spots increases with their decreasing surface in a simple relation enabling certain liquid volume to be drained, as understood by a skilled person.

[0023] In some embodiments, the device is implanted already with a part of the holes being preformed. In other embodiments, the device works without the drainage tube and/or without the absorbance plate, for example as trabeculectomy accessory. In still other embodiments, more than one device is implanted, whereby increasing the drainage efficiency or substituting a failed device. The invention may provide help in certain cases of closed-angle glaucoma.

[0024] The inner volume of the device, whether formed of a porous material or whether hollow, transports the liquid from a site of higher water thermodynamic activity to a site of lower water thermodynamic activity. The driving force may comprise the pressure difference, wicking phenomena, etc., but the final effects include lowering the damaging overpressure inside the eye. The device according to the invention drains fluid subconjunctivally, either under the conjunctiva or deeper.

[0025] In a preferred embodiment of the invention, the device consists of a specially designed drainage loop with preplaced opening points to be later opened by laser, the shape of the device being essentially toroid. In other preferred embodiment of the invention, the device consists of two parts, the first comprising a toroid drainage loop with opening points as described above, and the second part being a drainage container or collector/drainage plate; usually, the plate is connected with the toroid structure by a linear connector tube. FIG. 1 schematically shows both cases.

[0026] The device will preferably be implanted in patients with uncontrolled glaucoma and/or in patient with failed previous treatments including surgery and laser. The main features of a preferred device according to the invention include a looped drainage tube, drainage tube comprising laser-compatible wall membranes with laser-sensitive spots (for example due to the material type or due to the thinner structure) to eventually provide openings. In one embodiment, the device may comprise a bagel-shaped drainage plate with or without scleral patching from a donor. The scleral patch may be preferred in cases when there is not enough conjunctiva tissue to cover the implant or when the implant is too large.

[0027] An important feature of the device of the invention is that it has a fixed position within the eye, it is placed immovably and stably, without being prone to known complications of tube devices. After placing the device within the eye, the surface area of created openings may be gradually increased to enhance the drained volume in accordance with the measured intraocular pressure, enabling to adjust the permeability of the device exactly as needed in a very flexible and sensitive way (clinical titration). The drainage capacity of the device can be affected by several parameters, including the number of laser-sensitive spots per square centimeter of the torus, the average diameter of the spot, the number of implanted devices, the type of eventual drainage container (such as absorption plate), the type of the eventual connector between the plate and the toroid, the site of location of the absorption plate on the eye body, the thickness of the toroid wall, the material of the toroid surface, the material and structure (porosity) of the toroid inner volume, the diameter of the tube making the toroid, the size of the toroid body, the fraction of irradiated laser-sensitive spots on the torus, etc.

[0028] A person skilled in handling glaucoma will appreciate that various parameters combinations may provide various problems solutions. In some applications, bagel-shaped device will be implanted to transfer the eye fluid out of the eye, and the device will be laser irradiated to open the preformed spots, in several stages to gradually increase the filtered volume up to the value exactly needed for a desired steady state; thus, a laser-assisted titration of the filtration rate is provided, which can help to manage the intraocular pressure in a more flexible and sensitive way.

[0029] The means for surgical treatment of glaucoma according to the invention are relatively less invasive than known means when performed without a plate, and less irritating than known means when performed without a plate or donor patches.

[0030] During the surgery, the practitioner usually makes two perforations in the limbus through which the device is passed and locked. Usually, scars form which can make pressure on the device. In the case of flexible fibers, the fibers can become easily compressed thus compromising filtration rate. The device according to the invention is preferably made of a relatively rigid material that can support the pressure exercised by the scar or other structures.

[0031] The instant device will preferably be used with refractory glaucomas and for eyes in which there is a high probability for trabeculectomy failure. Refractory glaucomas comprise, for example, uveitis, steroid-induced, neovascular, aphakic, ICE-syndrome, post-keratoplasty, associated with retinal or corneal surgery, associated with pseudophakia, aphakia, trauma, epithelial and fibrous downgrowth, aniridia, and iridocorneal endothelial syndrome. Known glaucoma implants comprise a drainage tube through which aqueous humor drains from the anterior chamber to an aqueous collecting plate that is sutured posteriorly. In the known devices, the tube has a single intraocular opening and the inside of the anterior chamber is fixed only at the level of the chamber angle: the end of the tube is not fixed and may touch near structurescornea, iris and lens. Overfiltration and underfiltration are unpredictable negative outcomes. Free end of the tube is prone to dislocation and tube-related complication (i.e. corneal edema, cataract, hemorrhage, extrusion, failure etc.). The bagel-shaped glaucoma drainage device of the invention, either standalone or combined with plate device with adjustable filtration rate, preclude the drawbacks of the known devices. Drainage device has a bagel shape design, comprising an impermeable and laser insensitive membrane with preplaced laser sensitive spots to be opened according to the required liquid flow by laser. In one embodiment of the invention, the device has two independent drainage systems that are separated by an impermeable wall. In case a first drainage system fails, for example is obstructed, a practitioner can open a second drainage system, thus allowing the passage of the liquid humour through it, thus avoiding an additional surgery or other procedures. Different device diameters, and different membrane types may be applied; the drainage plate may be circular (bagel-shaped), and may have a collector plate (namely plate).

[0032] Parts of the device, for example extraocular part, may be coated with antifibroblasting material which prevents fibrovascular tissue formation around the device, such as, for example, mitomycin C and 5-FU. In one embodiment of the invention, the device is a silicone tubing which is implanted through two openings at the level of the anterior chamber angle of the eye. The implantation is guided by curved forceps, which helps to device to be inserted through one opening and to leave the eye through another. Subsequently, the ends of the tubing should be attached one to another and closed by lock, thereby rendering the device essentially toroidal shape (for example, see FIG. 5A); after the implantation the device is permanently sutured to sclera at the special neck of the device. The device efficiently drains the excessive fluid by itself (FIG. 2) or in connection with an absorption plate (FIG. 3). In the latter case, the lock may comprise a T-shaped or Y-shaped tube (FIG. 5B). In one embodiment, the base curve of the scleral part of the device (i.e. extraocular part) may have shape identical to the curve of the outer corneal curvature (i.e. limbal curvature) to be parallel to the anterior angle, and to allow exact fit of the device. In some embodiments, the intraocular part of the device can have the curvature reversed to the limbus curvature (i.e. true bagel form) or curvature parallel to the extraocular part (parallel to the limbus), allowing the device to be located at the level of the chamber angle only, and not to enter the anterior chamber deeply (FIG. 4). Outer parts may efficiently function as one-way valves to protect the eye from back flow of the fluids (FIG. 4). Extraocular and intraocular parts may have similar curves (parallel), so that there is no protrusion of the device to anterior chamber. The implantation may be located as subconjunctival, or below a scleral flap, with or without a donor patch. The device can be implanted in the lower part of the eye.

[0033] The device of the invention has no free movable ends and reduces usual tube-related complications considerably. The surgeon can adjust the filtration volume by means of the incremental increase of the openings effective surfacetitrationwhile employing laser, for example YAG. Said clinical titration of drainage volume, together with non-irritating character of the torroidal shape, imparts to the device great flexibility and sensitivity, enabling its superior performance in reaching the goal of shunting aqueous fluid out of the anterior chamber, bypassing the trabecular meshwork to increase outflow, and lowering the IOP.

[0034] While this invention has been described in terms of some specific examples, many modifications and variations are possible. It is therefore understood that within the scope of the appended claims, the invention may be realized otherwise than as specifically described.