WO1995008310A1

WO1995008310A1 - Implantable device for the treatment of ×demas

Info

Publication number: WO1995008310A1
Application number: PCT/IB1994/000284
Authority: WO
Inventors: François PITHON
Original assignee: Voir Et Vivre E U R L; Pithon Francois
Priority date: 1993-09-22
Filing date: 1994-09-20
Publication date: 1995-03-30
Also published as: AU7545594A; FR2710269A1

Abstract

Device (1) implantable in any human or animal living organism, intended to evacuate any liquid from an ÷dematic collection, comprising at least one draining tube (6) of which one upstream extremity (6a) is intended to be implanted in the serous cavity in overpressure conditions, and of which another downstream extremity (6b) is intended to be implanted in the evacuation zone, said tube presenting at least partly a sufficient flexibility so that it can be adapted to the shape of the part wherein it is implanted, and being made of at least one biocompatible material, characterized in that the tube presents on the major part of its length between its upstream extremity (6a) and its downstream extremity (6b), and particularly in the portion intended to be associated with the evacuation zone, a lateral permeability providing for a diffusion of substantially all the liquid taken through its upstream extremity (6a), from the inside to the outside and through the wall of said tube, but in a direction opposite to a cellular migration from the outside to the inside of said tube.

Description

IMPLANTABLE DEVICE FOR THE TREATMENT OF OEDEMAS

The present invention relates to devices or other systems, implantable in humans or animals for treating edematous collections.

The description below relates more particularly to devices implantable in the eye, both inside and outside the eyeball, making it possible to treat glaucoma, without, however, the scope of the invention be limited. Indeed, the device of the invention applies to the treatment of any edematous collection of the human and animal body such as cerebral, renal edema and hydrocephalus ...

Glaucoma is an eye disease, which can take acute or particularly severe forms, to the point of causing partial or total blindness in the patient. This disease is generally characterized *, by hypertonia of the eyeball, namely an increase in intraocular pressure, which increases the hardness of the globe and causes compression of the optic nerve, with a decrease in visual acuity.

In ophthalmology, glaucoma is most often treated by trabeculectomy. This operating technique consists in incising the corneo-sawn trabeculum, to create a valve evacuating the aqueous humor in overpressure towards the space under conjunctival. But to overcome healing phenomena, we can associate the introduction of a biocompatible drainage tube with the eye, allowing to remove excess aqueous humor from the anterior ocular chamber.

To this end, the upstream end of the drainage tube penetrates and is held in the anterior chamber, while the other downstream end is first implanted under the shutter sawn, then under the conjunctiva, where the aqueous humor is evacuated, to be diffused and absorbed by the surrounding tissues. The drainage tube has at least in part sufficient flexibility to adapt to the shape or local contour of the sclera.

Such a technique has shown its limits, in the sense that the drainage tube can be colonized by cell proliferation or fibrosis, to the point of gradually closing off, in particular at its downstream end. Under these conditions, glaucoma reappears gradually and requires a new intervention.

Incidentally, examples of this technique can be found in the disclosure of the invention WO-A-91 07195, WO-A-92 00112 and US-A-4 521 210, where the drainage tube or tubes are completely in the internal position and therefore open into the anterior chamber by flush with it. In experience, such a position is not satisfactory, because it does not prevent cell recolonization.

In addition, the device described in O-A-91 07195 requires the use of a special pocket placed in the sclera. The device described in O-A-92 00112 is not intrascleral; it is placed under the superficial layers of the cornea, which obviously cannot guarantee proper retention, even relatively short term. As for the device described in US-A-4 521 210, its complexity will be judged, in particular because it is necessary to use lateral support legs (cross shape), legs which moreover are likely to be a discomfort for the eye or being poorly tolerated by the body.

The present invention therefore relates to an implantable device comprising a drainage tube, overcoming the drawbacks of conventional trabeculectomies, and the other drawbacks mentioned above, by associating therewith the implantation of non-obturable drains. More specifically, the subject of the invention is a device making it possible to diffuse the bodily fluid to be evacuated such as the aqueous humor, while ensuring that it cannot be blocked for the entire duration of its implantation by cell colonies.

According to the invention, the drainage tube or tubes each have, over the major part of their length between the upstream end and the downstream end, and in particular in their part in contact with the discharge zone, a permeability lateral, making it possible to diffuse almost all of the liquid to be evacuated withdrawn by the upstream end, from the inside to the outside and through the wall of said tube, but opposing cell migration from the outside to the inside said tube. The tube is in a position that is not completely intrascleral and extends and emerges inside the anterior chamber.

The not entirely sawn path of the tube (s) means that their respective end exceeds the equator of the eyeball to lead into an area where the structures adjoining it are much less dense, which effectively prevents the obstruction or clogging of the drainage by scar processes. Typically for a human eye, the tube or tubes emerge from the sawn shutter with a length of between 1.5 and 3 mm.

According to the invention, a drainage tube then behaves as a lateral diffuser of the aqueous humor, and this in a particularly simple manner.

The present invention also presents the following execution methods: - according to a first embodiment, the drainage tube comprises, at least in its part in contact with the evacuation zone, a multiplicity of porosities with micro-perforations passing through its wall right through, and distributed throughout its lateral surface; according to another embodiment, the material of the drainage tube is continuous, that is to say non-perforated, but semi-permeable, at least from the inside towards the outside, thus allowing a continuous diffusion in the same sense, of aqueous humor, by simple permeation; preferably, each drainage tube is a hollow, porous fiber, in particular having a diameter between 0.3 and 1.2 mm, and a wall thickness of more than 50 micrometers; - The device according to the invention may comprise one or more drainage tubes, independent of each other; in the latter case, the drainage tubes can be connected or held together by a flat fastening means, for example by a wire link or of the matrix type encompassing them or else a biocompatible glue (in particular polyurethane), and the downstream ends of the tubes are spread out in the evacuation zone; it is important to point out here that the assembly holds by a simple bulge corresponding to the matrix or bonding point and does not include any fixing lug as in the aforementioned US disclosure; this limited thickening on the trajectory of the tubes makes it possible to fix the device by simple folding down of the sawdust flap, both in relation to its introduction into the anterior chamber and in relation to its emergence outside the sawdust flap around the ocular shell; the same remarks with regard to the fixing being applicable moreover in the case where there is only one tube;

- Preferably, the downstream end of the drainage tube is open; the material of the drainage tube is preferably hydrophilic, but can be chosen from the following flexible products, namely silicone, polymethyl methacrylate (abbreviated PMMA), and polyvinyldifluoroethylene (PVDF), hydrogel whatever it may be; preferentially the drainage tube is a hydrophilic hollow fiber and in particular a hollow fiber derived from cellulosic products, a hollow fiber made of type material ethylene / vinyl alcohol, polymethyl-methacrylate, simple polyacrylonitrile or coupled to sodium methallyl-sulfonate, polysulfone and any other combination of materials making it possible to produce a porous tubule such as those already used for artificial kidneys; the material of the drainage tube can also be chosen from rigid products such as a porous ceramic and in particular simple alumina, zirconia-alumina and tetragonal zirconia; all of these flexible or rigid materials which could have benefited from any type of surface treatment;

- For the drainage tube (s) produced, each consisting of a porous hydrophilic hollow fiber, the porosity is preferably between 10 and 95%.

Can be used to obtain a drainage tube according to the present invention, any biocompatible polymeric substance, as used to produce any intraocular lens capable of being implanted on the optical axis in the corneal thickness, in the anterior chamber of the eye, between the iris and the natural lens (resting against the latter), or in the lens sac in place of the natural lens, or in the vitreous compartment further back, and capable of correcting any form of optical anomaly (aphakia, high myopia, hyperopia, astigmatism, even presbyopia, and magnifying system for ocular degeneration).

In general, the materials selected must have the following characteristics or properties: preferably be micro-porous, both to simplify the production of the tube or tubes, and to avoid any invasion by cell proliferation, even late;

- be neither biodegradable nor absorbable, to allow permanent and lasting diffusion of the liquid to be evacuated; - be neither reactogenic nor irritant to not favor any local fibrosis reaction, hampering the effectiveness of the device in the medium term;

- of course be biocompatible, that is to say well tolerated by the human or animal organism, without any form of local or general toxicity; have a particularly smooth surface, that is to say exhibit no major roughness or irregularity by observation with an electron microscope for example.

Hydrogels and more generally any material used in artificial kidneys constitute preferred materials for obtaining the tube or tubes belonging to a device according to the invention.

The hydrogels or "gels containing water", are synthetic polymers absorbing water, of soft but firm consistency induced by their hydrophilicity and their insolubility in water. These hydrogels are obtained by copolymerization of monomers having water-solubilizing groups, for example hydroxyl, with other monomers, for example ethylene dimethacrylate. These hydrogels are widely used in ophthalmology, for example for corneal dressings.

For the application according to the invention, namely obtaining tubes or tubules, the hydrogels have proved to be well suited, since their hydrophilicity makes it possible to absorb water, while opposing a migration of cells and large molecules (PM greater than 40000 Dalton). Furthermore, they have good oxygen permeability, are optically transparent, and have been found to be mechanically durable.

As hydrogel, acrylonitrile / sodium methallyl sulfonate is preferred as having, in particular, a high permeability towards liquids, capable of ensuring a significant filtration in glaucoma. Her Biocompatibility is excellent, since in particular it is the most hemo-compatible of the high flux fibers known for artificial kidney.

As an example of such a material, reference will be made to the commercial reference AN69 sold by the French company HOSPAL.

With this latter material, comprising by weight 30% of non-crosslinked polymers and 70% of water, according to the invention, tubes and tubes with an outside diameter of 340 microns, an inside diameter of 240 microns were obtained and used, and by Consequently, a wall 50 microns thick. These tubes are glycerins before their use, have a high permeability, for example of the order of 60 ml / h / m ² / mm of Hg, thanks to an outside pore diameter of less than 100 Angstroms.

The surface condition of these hydrogel fibers, already satisfactory when they are obtained, can be further improved by an appropriate surface treatment, for example with treatment at room temperature, in one or more stages, with a long aliphatic chain with sequences at different temperatures.

The present invention is now described with reference to the accompanying drawings, in which:

- Figure 1 shows an anatomical sectional view of an eye and the sawdust flap, with respect to which a device according to the invention is implanted; Figures 2, 3, 4 show, in correspondence with Figure 1, the eyeball with the sawdust flap, under which a device according to the invention is implanted;

- Figure 5 shows in an enlarged manner, and with partial cutaway, a drainage tube forming part of the device shown in Figures 1 and 2, the pores being generally invisible to the naked eye. Once implanted in the eye and the ocular cavity 3, the device 1 according to the invention makes it possible to evacuate the aqueous humor from the anterior ocular chamber 4 towards the scleral shell 5. This device here comprises a plurality of drainage tubes 6, whose upstream or anterior end 6a is implanted in the anterior chamber 4 and whose other downstream or posterior end 6b is implanted under the conjunctiva 11 beyond the sawdust flap 8, the reference 9 representing the sclera and / or choroid. Each tube is made of a material biocompatible with the eye, in particular of a hydrophilic material capable of being wetted by the aqueous humor, for example hydrogel, and at the same time has sufficient flexibility to adapt to the shape of the scleral shell 5 and the eyeball. As shown in Figures 1 and 5 together, each tube 6 comprises, at least in its sclerotic part 6c, that is to say in its part disposed after implantation under the sawdust flap 8, and in the anterior chamber 4, a porosity or a multiplicity of micro-perforations 6d passing through its wall right through, and distributed throughout its lateral surface. The porous tubes ^v have openings less than one micron, to avoid any cellular invasion.

Depending on the case, a single tube may suffice, but as a general rule and to properly regulate drainage, 3 to 7 tubes will be used on average per eye.

As shown in FIG. 3, the drainage tube or tubes are implanted in the eye, after cutting a sawdust flap 8, which is then replaced by sewing according to FIG. 3, the corresponding surgical act being described below. after.

As already indicated, each of the tubes 6 can be replaced by a semi-permeable hollow fiber, such as those used in renal dialysis devices, that is to say made of a semi-permeable material, for example a micro-porous polymer, such as hollow fibers or hydrogels.

An embodiment of the present invention is now described, with one or more tubes each having micro-perforations, or a microporosity.

A drainage tube according to the invention is preferably delivered sterile ready for use and is implanted in a few minutes, under a microscope, during the intervention.

The drainage tube is then cut obliquely at its two ends to allow, in the anterior chamber, a sampling zone at its wider upstream end of the aqueous humor, and to more easily avoid any endothelial contact, by suitable rotation to the tube. At its downstream end, the cut is identical, both so that the tube can, if necessary, be turned over at the time of implantation, as to allow posterior contact as smooth and harmonious as possible.

The sterilization of the perforated drainage tube can be carried out:

1) either directly from a tube delivered sterile at the start of the intervention,

2) either after rinsing the tube in an ultrasonic tank, with an antiseptic and biocompatible product; this procedure usually requires 48 hours, but can be replaced by one of the procedures applicable to silicone;

3) either after exposure to vapors of ethylene oxide or Aldethylene (trade name).

The drainage tube is put in place during a simple trabeculectomy or trepanotrabulectomy performed with 1.7 mm Elliot drill bit, so that the drainage tube (0.7 mm) can be easily inserted diameter or less if three polymer fibers acrylonitrile or derivative are used), in a slightly larger rounded orifice. The drainage tube is then slid under the conjunctiva in a radial fashion, towards the equator of the globe which it must exceed behind.

The drainage tube can be fixed under the sawdust shutter, either by a separate point with a 10/0 prolene wire (0.2) by plating the bridge into the sclera and making a "dead turn" around the tube , or simply by closing the scleral flap, even if it has produced a passage strap for the tubule further on the ocular shell. Before tightening any possible point, it is important to ensure, to better protect the corneal endothelium, that:

1) the length which emerges in the anterior chamber is approximately 2 mm,

2) the oblique section of the upstream or anterior end of the tube is turned upwards, that is to say that the space between the endothelium and the drainage tube increases towards the pupil, due to the oblique section of the upstream end.

By way of indication and in relation to FIG. 2 representing a human eye whose cornea has a diameter of approximately 12 mm, the length of the tubes around the point 10 of their bundling is between 4 and 5 mm and their posterior part 6c extends for example over a length of between 8 and 24 mm.

Conjunctival closure is then practiced in a completely classic way, according to the surgeon's habit, knowing that an opening at a distance from the limbus seems more suitable. Thus, the implantation of an efficient drainage device represented only a simple and easy complement to add to a traditional surgical protocol: "trabeculectomy".

This same type of drainage device can be introduced in a comparable way into the space where the cerebrospinal fluid possibly overpressure to the surrounding connective tissue.

Claims

1. Device (1) implantable in any living human or animal organism, intended to evacuate any liquid from an edematous collection comprising at least one drainage tube (6), one end (6a) of which is called upstream and is intended to be implanted in the serous cavity in overpressure and of which another end (6b) called downstream is intended to be implanted in an evacuation zone, the tube having at least partly sufficient flexibility to adapt to the shape of the part in which it is implanted, and being made of at least one biocompatible material, characterized in that the tube has over most of its length between its upstream end (6a) and its downstream end (6b), and in particular in the part intended to be in relation to the discharge zone, a lateral permeability allowing diffusion of almost all the liquid withdrawn by its upstream end (6a), from the inside to the outside and by the wall of said tube, but opposing cell migration from the outside to the inside of said tube, and in that the tube is not completely in the intrascleral position.

2. Device according to claim 1, characterized in that it is intended to evacuate the aqueous humor from the anterior ocular chamber (4) towards the scleral shell (5) and that it comprises at least one tube (6) of which the upstream end (6a) is intended to be implanted in the anterior chamber (4) of the eye and the downstream other end (6b) of which is intended to be implanted under the conjunctiva beyond the sawdust flap (8) .

3. Device according to claim 1 or 2, characterized in that the material of the drainage tube (6) is continuous but semi-permeable, at least from the inside to the outside, and allows continuous diffusion in the same direction , liquid to drain.

4. Device according to claim 1 or 2, characterized in that it comprises a plurality of drainage tubes (6), independent of each other, or connected to each other by means of fastening flat.

5. Device according to claim 1 or 2, characterized in that the downstream end (6b) of the drainage tube (6) is open.

6. Device according to claim 1 or 2, characterized in that the material of the drainage tube (6) is preferentially hydrophilic, but can be chosen from silicone, polymethyl methacrylate, polyvinyldifluoroethylene, and hydrogels, derived products cellulosic products, ethylene / vinyl alcohol, polymethyl methacrylate, and preferably polyacrylonitrile simple or coupled to sodium methallyl-sulfonate, polysulfone and any other combination making it possible to produce a porous tubule, or among rigid products such as a porous ceramic and in particular a simple alumina, a zirconia-alumina and a tetragonal zirconia.

7. Device according to claim 1, characterized in that the drainage tube is made of polyacrylonitrile / sodium methallyl-sulfonate.

8. Device according to claim 1, characterized in that the drainage tube is a porous hollow fiber, in particular whose porosity is between 10 and 95%.

9. Device according to claim 1, characterized in that the drainage tube is a hollow fiber, in particular having a diameter between 0.3 and 1.8 mm, with a wall thickness of more than 50 micrometers.

10. Device according to claim 1, characterized in that the pores of the drainage tube have an average diameter less than 100 Angstroms.