ES2937954T3 - flexible stent - Google Patents

Abstract

A flexible stent structure (300) includes a plurality of axially spaced apart strut portions (302, 304, 305) that define generally tubular axial segments of the stent and are constructed to expand radially. A helical portion (303, 309) is axially interposed between two strut portions and has a plurality of helical elements connected between circumferentially spaced locations on the two strut portions. The coil elements extend helically between those locations and the length of a coil element is sufficient that, when the stent is in a radially expanded state, it can simultaneously withstand repeated axial compression or expansion and flexing. (Automatic translation with Google Translate, without legal value)

Description

DESCRIPTION

flexible stent

Background of the invention

The present invention relates generally to expandable tubular structures capable of being inserted into small spaces in living bodies, and more specifically to a stent structure that is capable of substantial and repeated flexing at points along the length of the stent. of its length without mechanical failures and without substantial changes in its geometry.

A stent is a tubular structure that, in a radially collapsed or compressed state, can be inserted into a confined space in a living body, such as an artery or other vessel. After insertion, the stent can be radially expanded to enlarge the space in which it is located. Stents are commonly characterized as balloon-expanding (BX) or self-expanding (SX). A balloon-expanding stent requires a balloon, which is usually part of a delivery system, to expand the stent from within and dilate the vessel. A self-expanding stent is designed, through choice of materials, geometry, or manufacturing techniques, to expand from a collapsed state to an expanded state once released into the desired vessel. In certain situations, forces greater than the expansion force of the self-expanding stent are required to dilate a diseased vessel. In this case, a balloon or similar device could be used to aid expansion of a self-expanding stent.

Stents are commonly used in the treatment of vascular and non-vascular diseases. For example, a collapsed stent can be inserted into a blocked artery and then expanded to restore blood flow in the artery. Prior to delivery, the stent would normally be retained in its collapsed state within a catheter and the like. At the completion of the procedure, the stent is left within the patient's artery in its expanded state. The health and sometimes the life of the patient depend on the ability of the stent to remain in its expanded state.

Many available stents are flexible in their collapsed state in order to facilitate delivery of the stent, for example into an artery. Few are flexible after they have been deployed and expanded. However, after deployment, in certain applications, a stent may be subjected to substantial flexing or bending, axial compression, and repeated displacement at points along its length, for example, when placing a stent in the superficial femoral artery. This can produce severe stress and fatigue, resulting in stent failure.

A similar problem exists with respect to stent-like structures. An example would be a stent-like structure used with other components in a catheter-based valve delivery system. Such a stent-like structure supports a valve that is placed in a vessel.

WO 00/30563 discloses a stent comprising a plurality of undulating band-like elements and a plurality of interconnecting elements connecting adjacent band-like elements.

Summary of the invention

The present invention provides a flexible stent as defined in claim 1. According to the present disclosure, a stent or a stent-like structure is constructed to have different types of tubular portions along its length. In general, there are strut parts and helical parts, where the strut parts are primarily built to provide radial expansion and radial strength, and the helical parts are primarily built to allow for repeated bending and compression and axial expansion. Bending and axial compression are likely to be required simultaneously, thus the stent structure allows for substantial repeated flexing while in an axially compressed or expanded state, and allows for axial compression while in a flexed state. Preferably strut parts are provided between the helical parts or helical parts are provided between the strut parts. In a preferred example, the stent is self-expanding and the strut portions and coil portions alternate along the length of the stent.

The stent is preferably constructed in such a way that, in the expanded state, the helical portions allow axial compression or expansion of approximately 20% (preferably between 15 and 25%) and at the same time allow bending with a radius of minimum curvature of approximately 13 mm of flexion (preferably between 10 mm and 16 mm).

According to another aspect of the disclosure, a helical part is fabricated from helical elements that extend helically around the axis of the stent between points on two different strut parts that are circumferentially separated by a distance that is more than about 25% of the circumference of the stent (which is equivalent to a 90 degree extension around the axis of the stent) when in its expanded state.

According to yet another aspect of the disclosure, a helical part is manufactured from elements coils extending helically around the axis of the stent between locations on two different strut portions. In one example, a helical element is bidirectional in that it extends first in one circumferential direction and then in the other between the two locations and has a peak.

In accordance with yet another aspect of the disclosure, a stent has a plurality of axially spaced apart strut portions that define generally tubular axial segments of the stent and are manufactured to be radially expandable. A helical part is axially interposed between two strut parts, and the helical part has a plurality of helical elements connected between circumferentially spaced locations on two strut parts. A helical element extends helically between these locations, and at least part of the helical part has a larger diameter than a strut part when the stent is in an expanded state. In an alternative example, at least part of the helical part has a smaller diameter than the strut part when the strut is in an expanded state.

In one example, the helical element is wound at least 90 degrees between the strut elements connected to the helical element. In another example, the helical element is wound at least 360 degrees between the strut elements connected to the helical element.

In an alternative example, stent grafts are formed from a biocompatible graft material that covers the exterior, interior, or both exterior and interior of the stent. The stent graft can have any embodiment of a stent structure of the present invention. Stent graft devices are used, for example, in the treatment of aneurysms, dissections, and tracheobronchial stenosis. The stent can also be coated with a polymer and/or drug-eluting material as known in the art.

Brief description of the drawings

The foregoing description, as well as other objects, features and advantages of the present invention will be more fully understood from the following detailed description of presently preferred, but nonetheless illustrative embodiments in accordance with the present invention, reference being made to the drawings. attachments, in which:

Figure 1A is a plan view of a first example of a stent in accordance with the present disclosure, the stent being shown in an unexpanded state;

Figure 1B is a plan view of the first embodiment of a stent in accordance with the present disclosure, the stent being shown in a radially expanded state;

Figure 2 is a plan view of a second example of a stent in accordance with the present disclosure; Figure 3 is a plan view of a third example of a stent in accordance with the present disclosure; Figure 4 is a plan view of a fourth example of the stent;

Figure 5 is a sectional end view of a fifth example of a stent in accordance with the present disclosure;

Figure 6 is a longitudinal side outline view of the same example as Figure 5;

Figure 7A is a plan view of one embodiment of a stent in accordance with the present disclosure;

Figure 7B is a plan view of another example of the stent in accordance with the present disclosure;

Figure 8 is a sectional end view of another example of the stent in accordance with the present disclosure; Figure 9 is a longitudinal side outline view of the example shown in Figure 8;

Figure 10A is a sectional end view of an alternative example of a stent in accordance with the present disclosure that includes a graft material covering an outer surface of the stent;

Figure 10B is a sectional end view of an alternative example of a stent in accordance with the present disclosure that includes a graft material covering an interior surface of the stent;

Figure 10C is a sectional end view of an alternative example of a stent in accordance with the present disclosure that includes a graft material covering an outer surface and an inner surface of the stent; Figure 11A is a side view of an alternative example of a stent in accordance with the present disclosure including a graft material attached to the strut portion, the graft material covering the strut portion and the coil portion;

Figure 11B is a side view of an alternative example of a stent in accordance with the present disclosure that includes a plurality of sections of a biocompatible graft material in which a space is provided between each of the sections of graft material;

Figure 11C is a side view of an alternative example of a stent in accordance with the present disclosure including a plurality of sections of a biocompatible graft material overlaid by graft material from adjacent sections;

Figure 11D is a side view of an alternative example of a stent in accordance with the present disclosure including a biocompatible graft material, the graft material having a bulge in the helical portions;

Figure 11E is a side view of an alternative example of a stent in accordance with the present disclosure including a biocompatible graft material, the graft material having a plurality of longitudinal openings on the helical portions;

Figure 11F is a side view of an alternative example of a stent in accordance with the present disclosure including a biocompatible material, the graft material having a bulge in the helical portions and the graft material having a plurality of longitudinal openings on the helical portions;

Figure 11G is a side view of an alternative example of a stent including a biocompatible graft material having a plurality of helical openings corresponding in accordance with the present disclosure to a pitch of the helical elements;

Figure 11H is a side view of an alternative example of a stent in accordance with the present disclosure including a plurality of sections of biocompatible graft material, each of the sections being attached to either the strut portion or the strut portion. helical in which a space is provided between each of the sections of graft material;

Figure 11J is a side view of an alternative example of a stent in accordance with the present disclosure including a plurality of sections of biocompatible graft material, each of the sections being attached to either the strut portion or the stent portion. helical in which adjacent sections of graft material overlap;

Figure 12A is a plan view of an alternative example of a stent in an expanded state;

Figure 12B is a plan view of the stent of Figure 12A in a folded state such that the spacing between the helical elements is the same along the length of the helical portions. Furthermore, the length of the stent is the same in both the collapsed and expanded states;

Figure 12C is a plan view of the stent of Figure 12A in a folded state such that the spacing between the helical elements changes along the helical portion. Furthermore, the stent is longer in the collapsed state than in the expanded state; and

Figure 13 is a plan view of one embodiment of a stent in accordance with the present disclosure.

Detailed Description of the Preferred Embodiments

Reference will now be made in greater detail to a preferred embodiment of the invention, an example of which is illustrated in the accompanying drawings. Wherever possible, the same reference numbers will be used throughout the drawings and the description to refer to the same or similar parts.

Figures 1A and 1B are plan views of a first example of the stent 10 according to the present disclosure shown in an unexpanded and expanded state, respectively. As used herein, the term "plan view" will be understood to describe an unrolled plan view. This could be thought of as cutting a tubular stent along a line parallel to its axis and laying it flat. Therefore, it should be appreciated that, in the actual stent, the upper edge of Figure 1A will adjoin the lower edge.

The stent 10 is fabricated from a material common to self-expanding stents, such as a nickeltitanium (Ni/Ti) Nitinol alloy, as is well known in the art. Typically, the stent is laser cut from a tube, for example, with a diameter of approximately 5 mm (Figure 1A). It is then expanded and adjusted to a diameter of approximately 8mm (Figure 1B), and for the above deployment would collapse to an appropriate diameter for its application, eg approximately 3mm. However, it is contemplated that the present invention may be applied to any type and size of stent.

The stent 10 is generally comprised of a strut portion 12 and a helical portion 14 with axially aligned strut portion 12 alternating with the helical portion 14. In a preferred embodiment, the strut portion 12 is positioned at either end of the stent 10 The strut part 12 can expand radially after deployment. Each strut portion 12 includes a strut ring 16 having a pattern of wave-shaped strut elements 16a that progresses circumferentially around the stent. Each strut element 16a has a width equal to the peak-to-peak distance around the stent and a length equal to the peak-to-peak distance along the length of the stent. It will be appreciated that the strut ring 16 could be partially straightened (vertically stretched in Figure 1B) in order to widen the strut elements 16a and reduce their length. This is equivalent to expanding the stent 10 radially. Preferably, the material from which the stent 10 is made is such that the strut element 16a will retain some wavy shape in a radially expanded state. For delivery, the stent would be folded and fitted into a catheter, and would expand after the catheter was inserted into the vessel and the stent advanced out of the catheter.

Each helical part is composed of a plurality of side-by-side helical elements 18, each of which is helically wound around a stent axis 10. The helical part 14 is radially expandable upon deployment and is compressible, expandable, and flexible in an unfolded state. The helical elements 18 can be connected between opposing individual wave parts of the strut element 16a of different strut parts 12. In this embodiment, each helical element 18 performs one complete rotation around the surface of the stent 10. However, they can make one partial rotation or more than one rotation The helical part is preferably constructed to allow repeated axial compression or expansion of approximately 20% (preferably between 15 and 25%) and simultaneously allow it to bend with a minimum radius of curvature of about 13mm (preferably between 10mm and 16mm), all without fail.

In general, an improvement in flexibility and axial compression can be realized if the helical element 18 is wound at least 90 degrees between the strut elements 16a connected to the helical elements 18. Alternatively, the helical element 18 is wound at least 360 degrees between strut elements 16a connected to the elements helical 18.

Figure 2 is a plan view of a second example of the stent 20 similar to the stent 10 of Figure 1. The main differences are in the structure of the strut portions 12' and that there are left and right handed helical portions (14R and 14L, respectively). Each strut part 12' comprises two adjacent strut rings 26, 27 connected by a stub 28. The closely opposite peaks of the strut elements 26a, 27a are connected by a stub 28 in such a way that each strut part 12' has a double strut ring structure. It would also be possible to connect multiple strut rings to form a larger strut part. The advantage of double or multiple strut ring strut parts is that they offer greater radial stiffness over single strut ring strut part and can stabilize the strut parts so they are less affected by axial forces.

In a right-handed helical part 14R, the elements 18 progress in a clockwise direction around the surface of the stent 10 and, in a left-handed helical part 14L, they progress in a counterclockwise direction. The helical elements 18 essentially float and allow relatively large displacements around and along the axis of the stent between the two strut ring portions at each end. In this embodiment, it will be appreciated that the diameter of the stent in each helical part 14R, 14l is the same as the diameter of the stent in the strut parts 12 on each side. However, this need not be the case, as will be apparent from the further embodiments discussed below. A benefit of using left and right handed helical parts is that when the stent is deployed, the two parts rotate in opposite directions, maintaining the relative rotational positions of the different axial parts of the stent.

Figure 3 is another example of the stent 30 in accordance with the present disclosure. It is similar to the stent 20 of Figure 2, except that the helical portions 34 include a helical element 38 that progresses bidirectionally (first counterclockwise and then clockwise) around the perimeter of the stent. 30 between the connection locations on two different strut parts 12'. The helical element 38 is wound at least 90 degrees from a first strut part 12' to the peak 35 and is wound 90 degrees from the peak 35 to a second strut part 12' in order to maintain flexibility. The unidirectional helical elements 18 of Figures 1A and 1B may allow adjacent strut parts to rotate relative to one another. The bidirectional helical elements 38 limit the amount of adjacent strut portions that can rotate about the axis of the stent relative to one another, but still provide bending and axial flexibility.

Figure 4 is a plan view of a fourth example of a stent in accordance with the present disclosure.

In this case, the stent 40 has the strut parts 12' of Figure 2 and the helical parts 14L, 14R (Figure 2) and the helical parts 34 (Figure 3). The advantage of this construction is that the combination of different types of coil elements allows for a mixture of properties as described herein, providing the opportunity for further optimization of overall stent performance for a given application.

Figure 5 is a sectional view perpendicular to the axis of a fifth example of the stent 30' in accordance with the present disclosure, and Figure 6 is a side contour view of the same example.

The stent has the structure shown in Figure 3, except that the coil parts 38' have a larger diameter than the strut parts 12'. In this construction, the radial stiffness of the helical parts is increased, but to a lesser degree than the strut parts.

When all parts of the stent have the same diameter, the coil parts cannot have as much outward force in a vessel as the strut parts when the strut is expanded. The geometry of Figure 6 will tend to force the helical parts to expand more than the strut parts, increasing the outward force of the helical parts, which equalizes the radial stiffness.

Nitinol structures are partially rigid, such that the force required to contract the structure back toward the collapsed state is generally greater than the force that continues to dilate the diseased vessel when the stent is in its expanded state. With some self-expanding Nitinol stents, a balloon is used to aid in the expansion/dilation of the vessel. The partial stiffness is enough to support the open vessel, but the outward force may not be enough to open the vessel (or it may take a longer period of time). Therefore, a stent with the type of geometry shown in Figure 5 would be a good resource to use in conjunction with balloon-assisted expansion or other applications that require additional expansive force.

Figure 7A is a plan view of another example of stent 40B' in accordance with the present disclosure.

The stent 40B' includes the strut member 42. The strut member 42 progresses helically from one end of the stent 40B' to the other. The strut member 42 forms the main body of the stent 40B'. In this embodiment, each strut element 44a is connected to a strut in a subsequent winding of strut member 42 by helical element 46. In this example, helical element 46 of helical portion 45 helically progresses less than one full rotation of 360 degrees around the stent 40B'. The helical element 46 progresses in a direction opposite to the direction in which strut member 42 helically progresses around stent 40B'.

Preferably, the coil elements 46 abut axially, forming a type of spring that allows a large degree of flexibility and axial expansion, while the strut member 42 provides radial resistance and retains the stent in its expanded state.

Figure 7B is a plan view of another example of stent 40C' in accordance with the present disclosure.

Stent 40C' is similar to stent 40B' and includes a strut member 42. Strut member 42 helically progresses from one end of stent 40C' to the other. The strut member 42 forms the main body of the stent 40C'. In the present embodiment, each strut element 44a is connected to a strut in a subsequent coil of strut member 42 by helical element 47. In this example, helical element 47 progresses helically around stent 40C' in the same direction in which progresses strut member 42 helically over stent 40C'. Stent 40C' includes transition coil portions 49 and strut portions 48 at each end of stent 40C' to allow strut portion 48 to be provided at either end of stent 40C'.

The stents 40B' and 40C' have the advantage that the flexible coil elements are more continuously distributed along the length of the stent and can provide more continuous flexibility.

Those skilled in the art will appreciate that various modifications to stents 40B' or 40C' are possible, depending on the requirements of a specific design. For example, it might be desirable not to connect all of the strut elements 44a in a specific wrap to a subsequent wrap, reducing the number of helical elements 46. The helical elements 46 may extend by less or any integer or non-integer multiple of a rotation. A stent could also be made from a plurality of tubular sections each having the stent construction 40B' or 40C' and joined longitudinally by another type of section.

Figure 8 is a sectional view perpendicular to the axis of an example of the stent 20' in accordance with the present disclosure, and Figure 9 is a side contour view of the same example.

The stent has the structure shown in Figure 1A, except that the coil portions 14' slope downward to a smaller diameter than the strut portions 12'. In this construction, the helical parts will exert less force on the vessel wall than if the helical parts had the same diameter. Reducing the force that the stent exerts on a vessel wall can reduce the amount of damage done to a vessel and provide a better performing stent.

Figures 10A-10C are sectional views perpendicular to the axis of the stent according to the present disclosure.

The stent grafts 60, 70 and 80 have a stent structure of the present invention of any of the examples described above with helical portions interposed between the strut portions. In one example, biocompatible graft material 62 covers the exterior 64 of stent graft 60, as shown in Figure 10A. Alternatively, biocompatible graft material 62 covers the interior of 74 of stent 70, as shown in Figure 10B. Alternatively, graft material 62 covers the exterior 64 and interior 74 of stent 80, as shown in Figure 10C. Graft material 62 can be formed from any number of polymers or other biocompatible materials that have been entangled or formed into a sheet or woven surface. Alternatively, the stent can be coated with a polymer and/or drug-eluting material as known in the art.

Figures 11A-11J are side profile views of stent grafts including features of the flexible stent structure of the present disclosure.

The stent graft 100 comprises a continuous cover of graft material 102 that covers the stent 10, as shown in Figure 11A. The graft material 102 is attached to the strut parts 12. The graft material 102 covers and is not attached to the helical parts 14.

The stent graft 110 comprises a plurality of sections 111 of graft material 112 that cover the structure of the stent, as shown in Figure 11B. The graft material 112 is attached to the strut parts 12. The graft material 112 covers at least a part of the helical parts 14 and is not attached to the helical parts 14. The space 115 is placed between the adjacent sections 111 of the graft material 112. The gap 115 typically varies in size between 0 (meaning no gap) and approximately 20% of the length of the helical part 14.

The stent graft 120 comprises a plurality of sections 121 of graft material 122 that cover the structure of the stent, as shown in Figure 11C. The graft material 122 is attached to the strut portions 12. The graft material 122 covers and is not attached to the helical portions 14. The sections 121 of the graft material 122 are positioned such that there is an overlap 125 between the adjacent sections 121 of the graft material 122. The overlap 125 typically ranges in size between 0 (meaning no gap) and approximately 40 % of the length of the helical part 14.

The stent graft 130 comprises a continuous cover of graft material 132, as shown in Figure 11D. The graft material 132 is attached to the strut portions 12. The graft material 132 covers and is not attached to the helical portions 14. The graft material 132 has a protrusion 133 on the helical portions 14.

The stent graft 140 comprises a continuous cover of graft material 142, as shown in Figure 11E. The graft material 142 has a plurality of longitudinal openings 144 on the helical portions 14.

The stent graft 150 comprises a continuous cover of graft material 152, as shown in Figure 11F. The graft material 152 has a protrusion 153 on the helical portions 14 and has a plurality of longitudinal openings 154 on the helical portions 14.

The stent graft 160 comprises a continuous cover of graft material 162, as shown in Figure 11F. The graft material 162 has helical openings 164 in the helical portions 14 that correspond to the pitch and angle of the helical portions 14.

The stent graft 170 comprises a plurality of sections 171 of graft material 172 that cover the stent 10, as shown in Figure 11H. Sections 171 may be attached to strut portions 12 or helical portions 14. Gap 175 is placed between adjacent sections 171 of graft material 172. Gap 175 will typically have a size ranging from 0 (meaning no there is space) and approximately 20% of the length of the helical part 14.

The stent graft 180 comprises a plurality of sections 181 of graft material 182 that cover the stent 10, as shown in Figure 11J. Sections 181 may be attached to strut portions 12 or helical portions 14. Sections 181 of graft material 182 are positioned such that there is an overlap 185 between adjacent sections 181 of graft material 182. The overlap 185 normally it will vary in size between 0 (meaning no space) and approximately 40% of the length of the helical part 14.

Figures 12A, 12B, and 12C are plan views of stent 200 in accordance with the present disclosure. Figure 12A shows stent 200 in an expanded state with space 202 between coil elements 18. Figures 12B and 12C show stent 200 in two different compressed states. In Figure 12B, the stent 200 is compressed in such a way that the space 212 between the side by side coil elements 18 is approximately the same throughout the coil portion 14. The size of the space 212 between the side by side coil elements side by side 18 can vary between 0 and approximately the size of space 202 in the expanded state, for example, as shown in Figure 12A. In other words, when the gap size is 0, there is no gap between the side-by-side helical elements 18 and the side-by-side helical elements 18 come into contact with each other.

The helical elements of the stent shown in Figure 12B have been wound around the stent a number of times such that in the collapsed state the total length 211 of the stent in the collapsed state is the same as the total length 201 of the stent. in the expanded state shown in Fig. 12A, thus eliminating shrinkage.

In Figure 12C, the stent 200 is compressed in such a way that helical element 18 elongates and the spacing 222 between side-by-side helical elements 18 varies along the axial length of the helical part 14. The size The size of the space 222 between adjacent helical elements 18 can vary between 0 and approximately the size of the space 202 in the expanded state, for example, as shown in Figure 12a. In other words, when the gap size is 0, there is no gap between the side-by-side helical elements 18 and the side-by-side helical elements 18 come into contact with each other. In Figure 12C, the total length 221 of the stent in the collapsed state is greater than the total length 201 of the stent in the expanded state.

An additional method can be provided to fold the stent in such a way that the length of the helical parts is shorter in the folded state than in the expanded state. For example, if the stent of Figure 12A were to be folded in a similar manner to that shown in Figure 12B, except that there is no gap between the side-by-side coil elements, the stent would have a length of 211 in the folded state. which is shorter than length 201 in the expanded state. In one example, a folding method provides a stent where the overall length is the same in the collapsed and expanded state and there is no gap between the coil elements in the collapsed state.

As described above, a preferred example of the stent is to allow repeated axial compression or expansion of about 20% while allowing a minimum radius of curvature of about 13mm to bend. One method of constructing a stent of the present invention with a specific goal of flexibility is to vary the ratio of the sum of the gap in the helical part to the total length. By increasing that ratio, the flexibility of the stent increases. This ratio will also be approximately the maximum axial compression that the stent will allow. It will be appreciated that the maximum axial compression for safety may be limited by other factors, such as stress in the coil elements.

Figure 13 is a plan view of a stent 300 in accordance with the present disclosure. The stent 300 is similar to other examples described above except that it includes various configurations and various axial lengths of the strut portions and various configurations and various axial lengths of the coil portions. The strut portions 302 positioned at the outermost part of the stent 300 include long strut elements 301. The long strut elements 301 have a length 311. The length 311 of the long strut element 301 is greater than the length 312 of the strut portions 304 positioned on the inside of stent 300. Long strut elements 301 provided at the ends of the stent may be advantageous in providing better anchorage and providing an area for adjacent stents to overlap, but do not impede the flexibility of the stent. the helical part. In some vascularizations, especially in the femoropopliteal arteries, the length of the diseased artery can be long, often longer than 10 cm. Multiple stents may be required to treat these long sections of diseased arteries. A common procedure in this case is to overlap the adjacent stents to cover the vessel to be treated. When some conventional stents overlap in this way, the mechanism that makes them flexible is hampered, and this artificial hardening can lead to many problems, including stent fractures. An advantage of the present invention is that the elements that allow for bending and axial flexibility (helical part) are different than the elements that provide a radial structure (strut part) such that the strut parts on adjacent stents can overlap and do not prevent the movement of the helical part and therefore the overall flexibility of the stent.

The helical portion 303 that is adjacent to the strut portion 302 comprises helical elements 18 that are connected to each strut element 301 of the strut portion 302. The helical portion 303 can provide a high percentage of surface area for optimized delivery. of a drug or other therapeutic agent. The strut part 304 is connected to the helical part 303 by the helical element 18 on each strut element 16a on the side 320 of the strut part 304 and is connected to the helical part 309 on any other strut element 16a on the side 321 of strut portion 304. Helical portion 309 provides a lower percentage of surface area and greater flexibility than helical portion 303. This type of configuration can provide a transition from a more rigid helical portion that has a high percentage of area superficial to a more flexible helical part.

The helical part 309 has a greater ratio of the sum of the lengths of spaces 323 to the length 324 of the helical part 309 than the sum of the lengths of spaces 325 to the length 326 of the helical part 303, such that the helical part 309 in general you will have more flexibility.

Strut part 306 has half as many thrust elements 305 as strut parts 302 or 304 and therefore generally has a more open area compared to either strut part 302 or strut part 304. A The advantage of a stent that includes a part that has a larger open area than other parts of the stent is that the larger open part of the stent can be placed over an arterial branch and not impede blood flow. While the strut part with a higher density of the strut element may impede blood flow.

The stent structure of the present invention, namely flexible coil portions flanked on each side by strut portions, provide an optimized structure where the strut portions stabilize a naturally unstable helical structure, and the coil portions provide network flexibility. . There is substantial design optimization potential in combining various embodiments of the two parts.

The flexible stents and stent grafts of the present disclosure can be placed within vessels using procedures well known in the art. Flexible stents and stent grafts can be loaded into the proximal end of a catheter and advanced through the catheter and released at the desired site. Alternatively, flexible stents and stent grafts can be carried around the distal end of the catheter in a compressed state and released at the desired site. Flexible stents or stent grafts may be self-expanding or expand by means such as an inflatable balloon segment of the catheter. After the stent(s) or stent graft(s) have been delivered to the desired intraluminal site, the catheter is withdrawn.

The flexible stents and stent grafts of the present disclosure can be placed within the lumen of the body, such as the vessels or vascular conduits of any mammalian species including humans, without damaging the luminal wall. For example, the flexible stent can be placed within a lesion or an aneurysm to treat the aneurysm. In one example, the flexible stent is placed in a superfemoral artery after insertion into the vessel, the flexible stent or stent grafts providing at least about 50% coverage of the vessel.

Although the presently preferred embodiments of the present invention have been disclosed for illustrative purposes, those skilled in the art will appreciate that many additions, modifications, and substitutions are possible without departing from the scope and invention as defined by the appended clauses. For example, a stent could be made with only right- or left-handed coils, or the coils could have multiple reversals in the winding direction instead of just one. Furthermore, the helical parts could have any number of turns per unit length or a variable pitch, and the strut rings and/or the helical parts could have unequal length along the length of the stent.

Claims (8)

1. Flexible stent (300) comprising: a helical part (303, 309) comprising a plurality of individual side-by-side helical elements (18) helically wound around an axis of said stent (300), said helical portion (303, 309) being radially expandable upon unfolding and compression, expanding and collapsing in an unfolded state; and a strut part (302, 304, 306) on each side of said helical part (303, 309), said strut part (302, 304, 306) comprising axially aligned strut elements (305, 16a) having a first end connected to said helical elements (18) of said helical part (309), said strut part (302, 304, 306) being able to expand radially upon unfolding, the stent (300) further comprising said one or more additional coil portions (303, 309) and said one or more additional strut portions (302, 304, 306), each of said one or more additional coil portions (303 , 309) is respectively connected to a second end of one of said strut parts (304, 306), said helical parts (303, 309) being respectively connected to said strut parts (302, 304, 306) in such a way that each of said helical parts (303, 309) is interposed between a pair of said strut parts (302, 304, 306), wherein a space length (323, 325) is the distance between two adjacent helical elements (18) of a helical part (303, 309), and one of said helical parts (309) has a higher ratio than a sum of space lengths (323) to a length (324) of the helical part (309) than a ratio of a sum of space lengths (325) to a length (326) of a second of said helical parts (303), and wherein one of said strut parts (306) has fewer strut elements (305) than a second of said strut parts (302, 304). The stent (300) of claim 1, wherein said coil elements (18) of each of said coil portions (303, 309) are wound in the same direction. The stent (300) of claim 1, wherein at least one of said strut portions (302, 304, 306) comprises a plurality of said strut elements (301, 305, 16a), said strut elements having strut (301, 305, 16a) of said strut part (302, 304, 306) a wave pattern of individual wave parts, each individual wave part having a peak and the peaks of said individual wave members being connected to each other yes by a union (28). The stent (300) of claim 3, wherein said at least one of said strut portions (302) is at either end of said stent (300). The stent (300) of claim 1, wherein said strut portions (302, 304, 306) and/or said coil portions (303, 309) may have a varied axial length along said stent ( 300). The stent of claim 5, wherein said strut elements (301, 305, 16a) of said strut part (302, 304, 306) have a wave pattern of individual wave parts, each part having individual wave a peak and each of said helical parts (18) is connected to a respective one of said peaks on one side (320) of said side strut elements (304) and some of said helical elements (18) are connected to some of said spikes on the other side (321) of said side strut elements (304). The stent (300) of claim 6, wherein each other of said spikes of said strut elements (304) is connected via a respective one of said coil elements (18). The stent (300) of claim 1, wherein said one of said strut portions (306) has half as many strut elements (305) as the second of said strut portions (302, 304).