WO2002047578A1 - Implant, method for inserting a reinforcing element, and method for producing an implant - Google Patents

Abstract

The aim of the invention is to provide an implant, which joins with a tissue as quickly as possible and yet is sufficiently compatible with the tissue. To this end, the invention provides an implant comprised of a tissue-compatible microporous material, which has at least one sturdy opening.

Description

 Implant, method for inserting a reinforcing element and method for producing an implant

The invention relates to an implant made of a tissue-compatible microporous material, a method for introducing a reinforcing element into a soft structure surrounded by a casing and a method for producing an implant from a blank.

For example, nets, braided ribbons and pillows are known in particular for surgical use and can be implanted. In this regard, polyamides or silicones are generally used as materials. However, these have the disadvantage that they do not grow sufficiently with the tissue due to their constellation. This leads to incompatibilities, such as encapsulation until the corresponding implant is rejected. The implants are mostly sewn to the tissue so that they do not slip. In the case of pillow implants in particular, this is aggravated by the fact that the size of these implants has to be determined and ordered before the surgical intervention, so that another surgical intervention is disadvantageously necessary if it becomes apparent during the operation that the intended implant is not of the required size equivalent. Since surgical intervention is always risks, a second surgical intervention is a major disadvantage.

On the other hand, implants made of a tissue-compatible microporous material are well known from the prior art and are used, for example, in different variations for cosmetic surgery or for accident surgery, e.g. B. offered as a tissue replacement. Expanded polytetrafluoroethylene (e-PTFE) is used in particular.

It is disadvantageous here that these known implants require a too long period of time for cell tissue to grow into their microporous structure, so that the implant is often moved out of its intended position, particularly in the case of an unfavorable movement. In many cases, this means that a further surgical intervention with the risks already mentioned is also necessary.

The object of the invention is to provide an implant which connects to a tissue as quickly as possible and which is nevertheless sufficiently compatible with the tissue.

The object of the invention is achieved by an implant made of a tissue-compatible microporous material which has at least one stable opening. With such an arrangement, a tissue that comes into contact with the implant can grow into the stable opening of the implant relatively quickly.

The tissue-compatible microporous material advantageously comprises labile openings. This is particularly advantageous since, in addition to the stable openings, which serve for the rapid ingrowth of cell tissue, almost any area of the implant is suitable for cell tissue to grow in, in particular in the medium or long term.

In addition to a first quick fixation option for the implant, the cell tissue that grows rapidly into the stable opening causes a particularly intimate connection between the tissue-compatible microporous material of the implant and the cell tissue arranged around the implant.

It is also advantageous that even with larger fillings, capsules do not form, as is the case with silicone or almost all other fixed implants. Furthermore, the implant according to the invention achieves considerable weight savings in comparison to implants that have been customary to date, such as silicone, table salt, soybean oil. In particular, leakage of the content of an implant is excluded with regard to the implant according to the invention. The implant does not suffer any serious injuries due to pressure or negative pressure. The implant is hardly destroyed by stab or other injuries. In order to ensure in particular the tissue compatibility of the implant, it is advantageous if the implant is made from an expanded polytetrafluoroethylene (e-PTFE). PTFE in particular has long been approved in surgery and has so far not caused any allergic reactions or intolerances.

Since an implant made of e-PTFE is very soft and elastic, pressure sores advantageously rarely or not at all occur. This is particularly advantageous in areas such as nerves, bones, vessels, which means that later pain in particular is virtually excluded.

With the expanded polytetrafluoroethylene, a microporous material is advantageously provided, the material of which is or can be expanded to such an extent that a tissue and / or a vessel can grow through the microporous material itself and thus the implant has a very intimate connection with the Tissue comes in.

The microporous material made of an expanded polytetrafluoroethylene and having stable openings has a ratio of preferably only 14% material and 86% air, in particular due to its porous structure.

The microporosity or the unstable holes ensure that tissue can penetrate or grow into the material in the medium or long term. The implant with the stable openings is suitable to fill up even the smallest tissue and / or nodal distances (both benign and malignant), which are easily visible, for example, after an operation through the sagging skin due to a lack of tissue, since the implant is preferably cut to any length and thus Almost any missing tissue, the shape and size of which has not yet been determined before surgery, can be replaced. For example, a tangle can be formed from the implant, which can be used instead of the removed tissue. The band-shaped implant, which is shaped into a ball or a similar three-dimensional arrangement, thus forms a lattice structure that tissue can permanently penetrate.

The implant according to the invention has a monosubstance which preferably does not contain any filling, the disadvantage of a diffusion out of liquids of conventional implants advantageously not being present.

It goes without saying that the implant according to the invention can be used not only in human medicine but also in veterinary medicine as a supporting element or as a tissue replacement.

In order to achieve an intimate connection between a tissue and the implant as quickly as possible using the stable openings, it is advantageous if at least one stable opening has a minimum diameter of 30 μm or 50 μm, which is essentially perpendicular to the implant surface, preferably a minimum diameter of 1 mm. on- has. This ensures that a tissue grows particularly quickly into the microporous material of the implant.

In particular, the openings can be chosen so large that tissues or similar structures penetrate these openings after the implant has been introduced to such an extent that they come into contact with the body's own tissue or with other body's structures. The resulting adhesions immediately stabilize the implant in the body. The contact also promotes a possible growing together, which then takes place much faster. It is also conceivable that - especially in the case of more stable or harder structures - it takes a little longer for them to penetrate or grow into the relatively large openings themselves. Nevertheless, this happens much faster than is the case with the smallest or unstable openings.

So that in particular sufficient implant material is still available, it is advantageous if at least one stable opening has a diameter of less than 5 mm, preferably perpendicular to the implant surface, preferably less than or equal to 4 mm.

It is particularly advantageous if the stable openings of the microporous material, in particular in the case of an implant under load in the opening plane, are opened in such a way that their minimum diameters are larger than the minimum diameters of the unstable openings. hereby the risk can be reduced that a recently inserted implant is displaced by an unfavorable movement or, for example, by a coughing process, such that a new surgical intervention is necessary.

This differentiates the implant according to the invention from known implants, since the pores of a known microporous material are closed depending on the load on the implant or from the outset in such a way that tissue ingrowth is severely impeded or almost impossible. This is due, among other things, to the fact that individual fibers of the known implants are tightened in many load states in such a way that they constrict or close the pores lying between them in such a way that a tissue surrounding the implant can hardly and if then slowly grow into the pores ,

However, the stable openings of the implant according to the invention remain so wide open at all application-related loads that a tissue surrounding the microporous material can advantageously grow rapidly into the stable openings and thus at least ensure basic fixation of the implant within the tissue as quickly as possible. In particular, the risk of slipping can be greatly reduced soon after the surgical intervention.

The size of the stable openings or the microstructure can be adapted to the respective application in the sense of the invention, wherein the stable openings should be large enough for a quick penetration of the respective tissue and the microstructure should be sufficiently firm for the necessary loads and sufficiently wide for a long-term ingrowth of the tissue.

It goes without saying that the stable openings can have almost any technically feasible hole shape. It is particularly advantageous if at least one stable opening has a circular or oval shape.

Furthermore, the stable openings can be arranged at any distance from one another, it being found that it is advantageous if the stable openings are at a distance of at least 0.5 mm, preferably a distance of at least 1 mm, from one another.

It is understood that the stable openings can generally be arranged in almost any arrangement on the implant.

It is advantageous, particularly with regard to a vaginal ligament, if the implant is tubular or band-shaped. The implant is preferably designed as an e-polytetrafluoroethylene tape. The implant can vary in terms of its width, height or shape, a rectangular shape with 1 mm and 10 mm width being preferred.

While an implant with connecting devices at both ends is preferably used in a vaginal ligament, one can The implant can be provided as a tissue replacement, preferably as a tape on a roll. An oval belt can be advantageous here, since it provides volume in a suitable manner. A rectangular band, which is easier to process, is particularly suitable for production. For these reasons, a tape as a tissue replacement is preferred to have a rectangular shape with a height of 1.5 mm and a width of 4 mm. In particular, the implant in the form of a band can be introduced freely into a conglomerate by a small incision or by one or more small incisions, thereby making it possible, among other things, to produce a loose implant of any size.

An embodiment variant provides that the implant has at least one

Has connecting device, by means of which another component with

> can be connected to the implant. In order in particular to be able to guide the rather soft implant through a tissue, it is advantageous if the implant has a connecting device to which, for example, a fixed component can be easily attached for guiding.

It goes without saying that, depending on the application, the connecting device can be attached to the implant intraoperatively or can already be arranged on the implant at the factory.

It is advantageous if the connecting device has means for positive connection. As a result, a good durable connection can be quickly established. In particular, the connecting device can have a thread. This ensures, for example, that almost any component can be quickly and easily attached to the implant. The component only needs a counter thread corresponding to the thread of the connecting device.

On the other hand, the connecting device can also have means for non-positive connection.

The person skilled in the art recognizes that the connection device of the implant can be implemented using a large number of technical devices, such as plug or clamp connections. It goes without saying that such a connecting device, in particular if it is already connected to the implant at the factory, is also advantageous independently of the other features of the invention, in order to ensure a reliable insertion of an implant quickly and reliably.

A further embodiment variant provides that a guide means is attached to the connection device with which the implant can be guided, in particular, through a tissue. The guide means makes it possible, for example, in an operative application to cure urinary incontinence, advantageously to guide the implant through the tissue of the body without serious injuries. The guide means preferably has no tactile and / or visible transition relative to the connecting device of the implant. For this purpose, the guide means can be a blunt needle or a pilot pin, for example. In particular, a blunt needle enables the implant to be inserted in the shortest possible time during an incontinence operation, the risk of tissue and / or vascular injury, for example injuries to the bladder and urethra, being greatly minimized.

In order to be able to advantageously guide the implant through a tissue, it is advantageous if the guide means is curved.

In order, in particular, to fasten the filling means to the implant quickly and easily, it is advantageous if the guide means has a coupling device which communicates with the connecting device of the implant. For example, the connecting device of the implant has an external thread and the coupling device of the guide means has an internal thread corresponding to the external thread, so that the guide means can be attached to the implant in a particularly simple manner.

So that, among other things, the risk of tissue injury can be further reduced, it is advantageous if the guide means is concave, preferably spherical, at the end opposite the coupling device. A relatively rough structuring of this end only injures the tissue to a reasonable extent. In the present context, the average radius of curvature of the tip should not be below 50 μ, preferably above 100 μ or 300 μ _. lie around Avoid injuries if possible. In this regard, the mean radius of curvature means a radius of a semicircle that can be reached from one side of the tip and then hit on the other side, in which both sides and the tip itself lie on this semicircle, while the other components of the tip are outside or are arranged on this semicircle.

Preferably, the concave end is polished to minimize the risk of injury.

The risk of tissue or vascular injuries can also be minimized if the coupling device of the guide means and the connecting device of the implant have an identical outside diameter. In this way, an almost seamless connection between the guide means and the implant can be established. Among other things, this considerably facilitates guiding the implant according to the invention through a body, since no transitions between the guiding means and the implant are a hindrance when guiding through a tissue. In addition, a protective tube or a protective sheath between the implant and a tissue that is pierced can be dispensed with.

In order to drive the guide means easily and yet gently through a body or through tissue, it is advantageous if the guide means has a vibration device. As a result of this, a high pressure need not be exerted on the filling agent, as was previously the case, in order to ses to move through the body, rather the implant moves almost independently through the tissue of the body due to the vibrations of the guide means. Among other things, this further reduces the risk of injury to internal organs, such as a bladder or blood vessels. In addition, this significantly shortens the operating time. For example, the implant can be inserted in less than 20 minutes during an operation to insert a vaginal ligament, possibly even under local anesthesia.

It goes without saying that the vibration device can be attached externally to the guide means as well as arranged internally in the guide means. In addition, the vibrating device can vibrate the guide means directly or by means of a flexible extension.

The vibration device is preferably arranged in the region of the coupling device or in the vicinity of the coupling device of the guide means, so that the latter can be inserted without further ado.

In order to reduce the overall costs, it is advantageous if the guide means is constructed in such a way that it can be used a second time at least after a first use.

The connecting device and / or the guide means and / or the coupling device of the guide means is preferably made of V4A. This makes them extremely durable and easy to sterilize. In addition, this material has already been tried and tested in medical technology.

It goes without saying that the devices and means mentioned above can also be produced from other materials. This is especially true if these materials also meet the strict medical standards.

In particular, when the previously described implant is used, it is possible to dispense with the hose or plastic shells previously required when pulling the implant into a tissue. Among other things, this also ensures that the implant lies particularly close to the penetrating tissue, which enables the tissue to grow into the microporous material of the implant more quickly. In addition, only a relatively small scar remains at a puncture point of the skin, which roughly corresponds to the diameter of the guide means, since the cut for puncturing need not be unnecessarily enlarged due to the identical outer diameter and the absence of a tubular sleeve or plastic sleeve. Among other things, this reduces a patient's wound pain.

It goes without saying that both the guide means described above and the vibration device or the coupling between the guide means and the implant are advantageous even without the other features of the invention. In the sense of the invention, the term “labile opening” means pores of the microporous material which, in the worst case, close completely or to such an extent when the load is introduced into the microporous material that at least temporarily there is no cell tissue in the unstable openings can grow in.

For the purposes of the invention, the term “stable opening” is understood to mean those pores of the microporous material which, when an application-related load is introduced into the microporous material, retain a minimum diameter even in the event of an unfavorable load introduction, so that they enter the stable openings almost at all times a cell tissue can penetrate or ingrow.

In order to be able to produce a microporous material particularly easily, as described above, it is advantageous if the microporous material is an expanded polytetrafluoroethylene (e-PTFE). With an e-PTFE material in particular, the fibrils can be expanded almost arbitrarily and thus a differently structured microporous material can be produced simply and inexpensively. In addition, e-PTFE has so far been completely inconspicuous, particularly with regard to medical applications with regard to intolerance or allergies.

The object of the invention is also achieved by a method for introducing a reinforcing element into a soft structure surrounded by an envelope, in which the reinforcing element, starting from a first region of the envelope, into the soft structure, Strengthening element up to a second area of the casing through the soft structure and out there, and in which the casing in the second area is made permeable to the reinforcing element from the outside and the reinforcing element is then guided through the second area to the outside.

It is advantageous if the reinforcing element is previously located in the second area of the casing from the outside, so that the casing can be opened in a targeted manner at this point.

It is particularly advantageous if a part of the reinforcing element is formed on the second region in order to make the casing permeable. The fact that the reinforcing element or at least part of it is imaged on the sheath makes it very easy to determine from the outside where the sheath the reinforcing element is located. As a result, the location of the casing for the reinforcing element can be made permeable in a targeted manner from the outside.

The method is suitable, for example, with regard to use in connection with aerosols surrounded by an envelope. Other soft materials which are surrounded by a harder shell and which are to be reinforced by a reinforcing element can also be treated in this way. In particular, this method is also suitable for pulling an implant into a body. Here, the casing or skin is first opened at a first point in such a way that the reinforcing element or an implant, if necessary with the aid of take the guide means in the material or in the body and is driven through this or this until the shell or the skin is reached at a second location. There the reinforcement means, the implant or the guide means can be localized and the shell or skin can be opened again from the outside, for example by a cut.

Furthermore, the object of the invention is achieved by a method for producing an implant from a blank, the blank being shaped intraoperatively into an implant. For example, since the extent of tissue removal can almost never be determined in advance of an operation, it is now possible to adjust the implant intraoperatively to the extent of tissue removal.

It is particularly advantageous if the blank is cut to length intraoperatively to form an implant. In particular, directly during an operation, for example for introducing a tissue replacement, it is advantageous if the implant can be adapted exactly to the operative conditions by the blank can be cut to length intraoperatively. In the case of a vaginal ligament, for example, this can happen - possibly even after days - when the implant has already been inserted.

Further advantages, goals and properties of the present invention are explained on the basis of the description of the attached drawing, in which exemplary embodiments of the implant according to the invention are shown. Show it

FIG. 1 shows a schematic view of a first arrangement variant of stable openings of an implant,

FIG. 2 shows a schematic view of a second arrangement variant of stable openings of an implant,

FIG. 3 shows schematic cross sections of some implants,

FIG. 4 shows a schematic illustration of an implant with a guide means and a vibration means,

Figure 5 is a schematic representation of another implant with a connecting device.

The implant 1 shown in FIG. 1 is made from a flat strip 2. The flat strip 2 in this case comprises a large number of holes 3, 4, 5, 6, 7 and 8, which are made as stable openings in the implant 1. Holes 3 to 8 are each arranged essentially at the same distance from one another in a longitudinal extent 9 of flat strip 2.

In contrast to this, the implant 10 has a plurality of holes 13, 14, 15, 16, 17 and 18 offset from one another in a longitudinal orientation 12 on its body 11, which is designed in the form of a flat band. The holes 13 to 18 are also in the longitudinal direction 12 on the body 11 of the implant 10, but the holes 13, 15 and 17 are closer to a side ten area 19 of the implant 10, whereas the holes 14, 16 and 18 are rather arranged in a side area 20 of the implant 10.

FIG. 3 shows cross sections 21, 22, 23, 24 and 24 A of different implants. The cross section 21 corresponds to an oval band, the cross section 22 corresponds to a flat band. The cross section 23 has a circular shape, whereas the cross section 24 is rectangular, in particular square. The reference number 24 A denotes a hose. On the one hand, this can be designed to be inherently rigid or, in itself, unstable.

The implant 25 shown in FIG. 4 comprises an expanded polytetrafluoroethylene band 26, which is arranged with a stainless steel screw 27 on an internal thread 28 of a bent needle 29.

The expanded polytetrafluoroethylene tape 26 has a large number of unstable openings 30 (numbered here only by way of example) and a large number of stable openings 31 (also numbered only by way of example).

The curved needle 29 comprises a polished spherical tip 33 in the area of its tip 32. Any rounded tip that has an average radius of curvature greater than 50 μ, preferably greater than 300 μ, can be used as the tip.

The implant 25 or its bent needle 29 has a vibrator 35 in an area 34, which is preferably arranged in the vicinity of the internal thread 28. By means of the vibrator 35, the needle 29 is in particular in the area of the polished spherical tip 33 set in vibration such that the implant 25 can advantageously be moved in the pushing direction 36 by a tissue 36A. In order to reach the tissue 36 A with the implant 25, a skin 36 B, which is arranged around the tissue 36 A, is pierced, if necessary. This can be done using known methods, such as a small incision, so that a pointed needle that can pierce the skin independently can be dispensed with. Accordingly, the guide means or the implant 25 can then also be guided out again by leading it to the skin 36B and localizing it there. The guide means or the implant 25 can then be removed by a small incision.

The vibrator 35 transmits vibrations to the needle 29 of the implant 25 by means of an extension 37.

The implant 38 (FIG. 5) comprises a plurality of stable openings 39 (numbered here only as an example) and at one end 40 a screw 41 which is clamped with its area 42 to a polytetrafluoroethylene tape 43 of the implant 38.

Claims

claims:

1. implant (1; 10; 25; 38) made of a tissue-compatible microporous material, characterized by at least one stable opening (31; 39).

2. Implant (1; 10; 25; 38) according to claim 1, characterized in that the tissue-compatible microporous material has labile openings (30).

3. Implant (1; 10; 25; 38) according to one of claims 1 or 2, characterized in that the implant (1; 10; 25; 38) is made of an expanded polytetrafluoroethylene (e-PTFE).

4. Implant (1; 10; 25; 38) according to one of claims 1 to 3, characterized in that at least one stable opening (31; 39) has a minimum diameter of 30 μm or 50 μm, preferably perpendicular to the implant surface has a minimum diameter of 1 mm.

5. Implant (1; 10; 25; 38) according to one of claims 1 to 4, characterized in that at least one stable opening (31; 39) has a diameter of less than 5 mm, preferably perpendicular to the implant surface, preferably a diameter of less than or equal to 3 mm.

6. Implant (1; 10; 25; 38) according to one of claims 1 to 5, characterized in that the stable openings (31; 39) compared to the unstable openings (30), in particular in the case of an implant under load in the plane of the opening (1; 10; 25; 38) are opened in such a way that their minimum diameters are larger than that

Minimum diameter of the unstable openings (30).

7. Implant (1; 10; 25; 38) according to one of claims 1 to 6, characterized in that at least one stable opening (31; 39) has a circular or oval shape.

8. implant (1; 10; 25; 38) according to any one of claims 1 to 7, characterized in that the stable openings (31; 39) a distance of at least 0.5 mm, preferably a distance of at least 1 mm, from each other exhibit.

9. implant (1; 10; 25; 38) according to one of claims 1 to 8, characterized in that the implant (1; 10; 25; 38) is tubular or band-shaped.

10. The implant (1; 10; 25; 38) according to one of claims 1 to 9, characterized in that the implant (1; 10; 25; 38) has at least one connecting device by means of which a further component with the implant can be connected.

11. The implant (1; 10; 25; 38) according to claim 10, characterized in that the connecting device has means for positive connection.

12. Implant (1; 10; 25; 38) according to claim 10 or 11, characterized in that the connecting device has a thread.

13. implant (1; 10; 25; 38) according to claim 10, characterized in that the connecting device has means for non-positive connection.

14. Implant (1; 10; 25; 38) according to one of claims 10 to 13, characterized in that a guide means is connected to the implant by means of the connecting device, with which the implant (1; 10; 25; 38), in particular can be passed through a fabric.

15. implant (1; 10; 25; 38) according to claim 14, characterized in that the guide means at the end opposite the coupling device is concave, preferably spherical.

16. The implant (1; 10; 25; 38) according to claim 15, characterized in that the concavely curved end is polished.

17. The implant (1; 10; 25; 38) according to one of claims 14 to 16, characterized in that the guide means is a blunt needle (29).

18. Implant (1; 10; 25; 38) according to one of claims 14 to 17, characterized in that the guide means is bent.

19. Implant (1; 10; 25; 38) according to one of claims 14 to 18, characterized in that the guide means has a coupling device which communicates with the connecting device of the implant (1; 10; 25; 38).

20. The implant (1; 10; 25; 38) according to claim 19, characterized in that the coupling device of the guide means and the connecting device of the implant have an identical outer diameter.

21. Implant (1; 10; 25; 38) according to one of claims 14 to 20, characterized in that the guide means has a vibration device.

22. Implant according to one of claims 1 to 21, characterized in that the microporous material consists of a large number of fibrils, the fibrils being connected to one another in groups in the region of their ends.

23. Implant according to claim 22, characterized in that the fibrils form unstable openings over 30 μm or 50 μm.

24. A method for introducing a reinforcing element into a soft structure surrounded by a sheath, in which the reinforcing element extends from a first region of the sheath into the soft structure up to a second region of the sheath through the soft structure and outwards there is performed, characterized in that the shell is made permeable to the reinforcing element from the outside in the second area and the reinforcing element is then guided through the second area to the outside.

25. The insertion method according to claim 26, characterized in that the reinforcing element is previously located in the second region of the casing from the outside.

26. Insertion method according to one of claims 24 or 25, characterized in that a part of the reinforcing element is imaged on the second region in order to make it permeable.

27. A method for producing an implant (1; 10; 25; 38) from a blank, characterized in that the blank is shaped intraoperatively into an implant (1; 10; 25; 38).

28. Manufacturing method according to claim 27, characterized in that the blank is cut intraoperatively.