Patent Application
20080300665
This patent application claims priority to German Patent Application No. 10 2007 025 921.4, filed Jun. 2, 2007, the disclosure of which is incorporated herein by reference in its entirety.
The present disclosure relates to a medical implant and, in particular, a stent having a main structure composed of deformable struts, which is preferably machined from a tubular blank by laser cutting. Alternative production methods, for example, laser sinter rapid prototyping, are also conceivable.
Medically implantable stents are known in various embodiments, the typically laser-cut struts making use of shaped elements, such as ring segments, spirals, axial connectors, and the like, in their main structure. The connection between these various strut structures is fundamentally a material bond because of the production method. This means that the shape changes of the stent required for medical use upon application from a catheter, for example, are to be implemented by a deformation of the stent material itself. Deformations of this type may occur elastically or also plastically, the limits for such a deformation being materially dependent and thus possibly also very strongly restricted. Furthermore, material bonds have the property of transmitting forces both in the compression and also in the traction direction. For relatively small deformations in the elastic range, the transmission properties are direction independent in this case. A very flexible connection in the compression direction also automatically has a high flexibility in the traction direction for small deformations. This is also true for rigid connections. For example, the mechanical properties of stents constructed according, for example, to U.S. Pat. No. 5,102,417 may also only be designed to a limited extent as a function of the load direction due to the material bond of the strut structures. This may have a disadvantageous effect on the properties of a stent under bending load, for example. A very soft deformation behavior on the compression side, but a slight deformation on the traction side may be desirable here to maintain a tubular external contour which is simultaneously adapted as well as possible to the blood vessel with overall low bending stiffness.
Braided stents represent a further construction of medical implants, in particular stents. Braided stents are known, for example, from U.S. Pat. No. 7,001,425 or U.S. Pat. No. 6,342,068. The braided structure without material bonds allows large relative movements between crossing wires in these implants, which provides the stents with comparatively high flexibility. The absorbable radial forces are comparatively low for this stent type. Fundamentally, a pronounced length change occurs upon stent expansion or compression, which is generally undesirable. Furthermore, bending of the stent is connected to a relatively strong reduction of the cross-sectional area which may have flow through it.
Retractable stents represent a special case. They are distinguished in that, after a partial release from the insertion system, the stents may be retracted back therein, to perform repositioning in the vessel, for example. A stent of this type is known, for example, from U.S. Pat. No. 7,037,331. To ensure the retractability, the structure of such a stent must be completely cross-linked so that no free ends exist within the structure which could get caught upon retraction into the release system. This circumstance makes stents constructed in this manner comparatively resistant to bending which makes good adaptation to strongly contorted vessels more difficult.
An open-celled stent, as described in U.S. Pat. No. 7,037,330, does have lower bending stiffness but may not be retracted because of the free ends within the structure and tends to deviate strongly from the desired tubular external contour under bending strain.
The present disclosure describes several exemplary embodiments of the present invention.
One aspect of the present disclosure provides a medical implant, in particular a stent, comprising a main structure composed of materially bonded deformable struts, machined from a tubular blank by laser cutting, further comprising a fine structure, attached to the struts of the main structure, made of a wire-like or thread-like material.
One aspect of the present disclosure provides a medical implant and, in particular, a stent having a main structure composed of deformable struts in such a manner that while maintaining reasonable absorbable radial forces, a high flexibility is ensured in the bending direction with optimum surface coverage and cross-linking density, without losing the tubular external contour. Another aspect of the present disclosure provides retractable stents having greatly improved bending flexibility.
One feature of laser-cut implants, which allow deformations only through comparatively high elastic or plastic strain of the material, may be combined with the features of braided and/or woven implants by this combination. The condition for a retractable stent concurrently having low bending stiffness is thus also provided.
According to at least one exemplary embodiment of the present disclosure, the fine structure has at least one wire or thread which is connected to the main structure on at least one attachment point loosely, in a formfitting manner, materially bonded, by gluing or by a fixing thread. Because of the selection capability among various attachments between fine structure and main structure, the stent according to this embodiment may be adapted especially well to the desired intended purpose. Further exemplary embodiments relate to constructive details for the connection of wire or thread to the main structure, in whose context reference is made to the description of the exemplary embodiments to avoid unnecessary repetitions.
Further exemplary embodiments relate to the assignment of the fine structure to a main structure made of helical peripheral meandering struts. Reference is also made here to the corresponding passages of the description of the exemplary embodiments to avoid unnecessary repetitions.
According to a further exemplary embodiment, the fine structure of the wire or thread forming the implant has a microstructure itself to expand its functionality. Thus, wire or thread may be composed of two or more materials so that multicomponent layered or composite systems may be produced relatively simply, for example. Structures in the form of wires or threads have the specific advantage that they may be produced as semifinished products in endless manufacturing and subsequently installed in the appropriate configuration in the implant. Thus, for example, a combination of a stable biocompatible material with a degradable polymer which, as a coating charged with active ingredient, acts as a medication depot, is to be mentioned. If the fine structure is a thread, it may in turn be impregnated with polymer which provides the advantage of better ability to be incorporated than the application of an active ingredient combination on the surface of a metallic structure.
Further material combinations may relate, for example, to the coating of the wire or thread surface with silicon carbide to improve the biocompatibility or the incorporation of an x-ray-opaque material in the wire or thread. Thus, for example, a wire may be provided with a coating or a core made of x-ray-opaque material.
According to a further exemplary embodiment of the present disclosure, the wire or thread may be implemented as a traction element for retracting the implant into a contracted state. In this context, it is advantageous that no separate constructive element is required for the retraction of the implant because the fine structure in the form of the wire or thread, which is part of the implant, merely has to be continued from the implant and may be pulled out as an attack element to retract the implant.
Various aspects of the present disclosure are described hereinbelow with reference to the accompanying figures in which like reference number refer to like parts.
The main structure 1 has a fine structure, identified as a whole by part number 4, superimposed, which is applied in various configurations in
In the exemplary embodiment shown in
In the exemplary embodiment shown in
In a further exemplary embodiment, as shown in
Finally,
It is also to be noted that in all exemplary embodiments according to
The various possibilities for how a wire/thread 5 may be attached to a strut 2 of the main structure 1 will now be explained on the basis of
In
The welding/soldering/gluing shown in
In
In the exemplary embodiment shown in
In the exemplary embodiment from
Various exemplary embodiments of the wire/thread 5 are illustrated in regard to a microstructure integrated therein in
In the exemplary embodiment shown in
In the exemplary embodiment shown in
Moreover, material combinations of three materials (Mat1, Mat2, Mat3) may be inferred from the following Table 1, as they may be implemented in the exemplary embodiments from
The alloy “Nitinol” is a superelastic structural material. Platinum is used to improve the x-ray visibility of the stent. The cited polymers may be implemented as both degradable and also having long-term stability. They may, as already explained above on the basis of the drawings, be used as an active ingredient carrier for so-called “drug-eluting applications”.
A non-superelastic material may also be used for the structural material (Mat1), for example, chromium-nickel and cobalt-chromium alloys, tantalum, titanium, niobium, and their alloys.
All patents, patent applications and publications referred to herein are incorporated by reference in their entirety.
| Number | Date | Country | Kind |
|---|---|---|---|
| 10 2007 025 921.4 | Jun 2007 | DE | national |
