AU2012244361B2

AU2012244361B2 - Stent valves and uses of same

Info

Publication number: AU2012244361B2
Application number: AU2012244361A
Authority: AU
Inventors: F. Joseph Obermiller; Francisco Jose Osse; Patricia E. Thorpe
Original assignee: Cook Inc; Cook Biotech Inc
Current assignee: Cook Inc; Cook Biotech Inc
Priority date: 2000-01-31
Filing date: 2012-11-02
Publication date: 2013-08-29
Anticipated expiration: 2021-01-31

Abstract

Abstract The invention includes a medical device and more specifically relates to a valve found generally within a frame. 5 In a preferred device, the frame may comprise a self-expanding stent frame, and the valve has at least one expandable and contractible pocket member within the stent frame for resisting and permitting fluid flow, respectively.

Description

AUSTRALIA Patents Act COMPLETE SPECIFICATION (ORIGINAL) Class Int. Class Application Number: Lodged: Complete Specification Lodged: Accepted: Published: Priority Related Art: Name of Applicant: Cook Biotech Incorporated and Cook Incorporated Actual Inventor(s): Francisco Jose Osse, Patricia E. Thorpe, Joseph F. Obermiller Address for Service and Correspondence: PHILLIPS ORMONDE FITZPATRICK Patent and Trade Mark Attorneys 367 Collins Street Melbourne 3000 AUSTRALIA Invention Title: STENT VALVES AND USES OF SAME Our Ref: 956805 POF Code: 236821/307799, 482199 The following statement is a full description of this invention, including the best method of performing it known to applicant(s): 6006q -2 STENT VALVES AND USES OF SAME 5 The present application is a divisional application from Australian patent application no. 2009202970, the entire disclosure of which is incorporated herein by reference. Background 0 Technical field of the invention: The invention includes a medical device and more 5 specifically to a valve found generally within a frame. In preferred devices the frame is comprised of a radially expandable stent which can be delivered through a delivery device such as a catheter. !0 Background of the invention: Lower extremity venous hypertension in addition to venous insufficiency is a major cause of morbidity in the United States. Symptoms of venous disease include lower extremity edema, varicosities, skin pigmentation changes, skin 25 ulceration, and general poor circulation. One solution to this problem is to replace the defective valve or the vein with a valve assembly. Current valves include a pressure responsive, pressure directed ball movement valve assemblies. The problem with 30 mechanical ball valves is that mechanical valves are susceptible to clot formation. Additionally, there are problems associated with long-term wear and tear on the device. Artificial valves such as biological valves are also known. Biological valves include homografts, allografts, and 35 xenografts. Problems associated with some biological valves include the supply of the valves, immunity response, or - 3 problems associated with matching the size with the donor. Finally other problems associated with valve repair include placement problems in which the device cannot be repositioned once it is ejected from the placement catheter, 5 leakage that occurs around the valve, and emboli formation. In light of this background, there remains a need for alternative and improved devices and methods for providing valvular function within vessels of the body. The present invention is addressed to these needs. ) The discussion of the background to the invention included herein including reference to documents, acts, materials, devices, articles and the like is intended to explain the context of the present invention. This is not to be taken as an admission or a suggestion that any of the material referred 5 to was published, known or part of the common general knowledge in Australia as at the priority date of any of the claims.

-4 Summary of the Invention Disclosed is a medical device comprising a frame that has a valve generally located within. In preferred forms of the 5 invention, the frame is comprised of a radially-expandable stent (including especially a self-expanding stent), which can be delivered through a delivery device such as a catheter, and then deployed and expanded at a target site in a body lumen such as an artery or vein. For example, in one preferred use, ) such a stent and method are used to treat incompetent veins in the legs or feet. Viewed from one aspect, the present invention provides a percutaneously-implantable vascular valve device, comprising: a 5 percutaneously-implantable frame having a proximal frame end, and a distal frame end; and a plurality of attached structures separately fabricated from but attached to the frame, each attached structure comprising a hole defined completely through the attached structure; at least two valve leaflets comprising ) flexible biomaterial and located at least partially within the frame when the frame is in an expanded configuration, the at least two flexible valve leaflets forming a valve opening occurring between upper portions of the leaflets, and wherein the leaflets are supported on the frame at least in part via 5 the attached structures; and a mechanism inward of the frame and holding together the upper portions of the flexible biomaterial of adjacent leaflets defining the valve opening. 0 -5 Viewed from another aspect, the present invention provides a percutaneously-implantable vascular valve device, comprising: a percutaneously implantable frame having a proximal frame end and a distal frame end; a plurality of attached structures 5 separately 10 fabricated from but attached to the frame, each attached structure comprising a hole defined completely through the attached structure; at least two valve leaflets comprising pericardium and located at least partially within the frame when the frame is in an expanded configuration, the at least D two flexible valve leaflets forming a valve opening occurring between upper portions of the leaflets, wherein the leaflets are supported on the frame at least in part via the attached structures; a mechanism inward of the frame and holding together the upper portions of the adjacent leaflets defining 5 the valve opening; and a sheath comprised of synthetic material partially covering an outer surface of the percutaneously implantable frame.

-6 [This page is intentionally left blank] Brief Description of the Drawings FIGs. 1A to 3 demonstrate one embodiment of the invention comprising a stent. 5 FIGs. 4 to 8 demonstrate other embodiments of the present invention comprising the valve. FIGs. 9 to 11 demonstrate embodiments that illustrate exemplary ways of attaching a plurality of stents. FIGs. 12 to 15 demonstrate exemplary embodiments of the ) valve configuration in a variety of stent embodiments. FIG. 16 demonstrates one aspect of the invention in situ. FIGs. 17 to 19 demonstrate other alternative embodiments. FIG. 20 depicts a medical assembly of the invention including a stent valve and a delivery device for the stent 5 valve.

- 8 Detailed description of the invention With reference to FIG. 15, shown is one embodiment of the present invention. The invention includes a frame such as a 5 wire stent that has a lumen extending therethrough. Near one end of the stent is the valve assembly comprising some leaflets or cusps. A valve opening is generally located between the leaflets through which fluid flows. Although shown as a two leaflet valve, equally the invention can comprise, in any 3 embodiment described herein, at least one leaflet such as two, three or four leaflets. With respect to FIGs. 1A, 1B, and 1C, a frame is partially shown. The frame can comprise a stent 20. Choices of stent include a self expanding stent or a non-self expanding stent. 5 In one embodiment of the present invention stent 20 is a self expanding stent such as the Gianturco stent available from Cook Inc. of Bloomington, IN as described in U.S. patent 4,580,568, the entire disclosure of which is expressly incorporated by reference herein. Such stent can be any length, but in one 3 embodiment, the stent is about 15 mm long. Stent 20 includes a plurality of bends 22, which generally form the area in which the stent struts 24 reverses direction. Bends 22 are generally rounded to provide an atraumatic condition. Since the stent 20 is generally located in a vessel or body lumen of some type, :5 the stent 20 can be cylindrical and therefore has a stent diameter 21 (shown in FIG. 3). In another embodiment, the stent 20 can also have a plurality of connectors 26 that connect adjacent struts 24. One way to provide a connector 26 is to dispose a solder bead between the adjacent struts. 0 However connector 26 can also be a suture, weld, adhesive, rod, clamp, or other well-known ways to connect adjacent struts 24. Connector 26 provides several non-critical advantages. Connectors 26 can attach adjacent struts 24 to minimize or prevent flaring of the ends of the stent 20. Furthermore, -9 connector 26, if placed near the bend 22, can create a hole 28 wherein the boundaries of the hole are the wires of the stent operating in general conjunction with the connector 26. This creates a hole 28 through which a thread or suture can run. 5 However, as shown in FIG. 1C, a separate prefabricated hole can be created by separately attaching a hole assembly, such as a cap 29 over the bend 22. In any case, one benefit of the connector 26 or cap 29 is that they increase the radiographic visualization of the invention. Particularly, if the connector ) 26 is a solder bead, it has increased radiopacity. With respect to FIGs. 2A and 2B, shown is part of the stent in which connector 26 attaches adjacent struts 24. As mentioned above, a thread or suture can be threaded through the hole 28. A proximal suture 30 can be sewn through the stent 5 proximal bends 22 or stent proximal ends 31 of the stent. Similarly, a distal suture 32 can be sewn through the stent distal end 33 or the stent distal bends 22 of the stent. One way to thread the suture is shown in FIG. 2B wherein the suture 35 (generically any suture) runs over the strut 24 to enter the ) hole 28, through hole 28 to come behind the same strut 24, over the strut 24 and across to the adjacent strut 24 running over the adjacent strut 24, behind the adjacent strut 24 to come from behind and through hole 28, and then run subsequently over adjacent strut 24. Once the struts are connected via the 5 suture, the suture can be pulled to a predetermined tightness to control the overall stent size. Accordingly, the stent can be so constructed to have a predetermined stent perimeter 34. To this end, the stent lumen 36 will also have an appropriate size. The stent can be constructed so as to have a different o perimeter length at the proximal or distal ends. With regard to FIG. 3, shown is a cylindrical stent 20 that has the proximal and distal sutures running through the bends 22 or holes 28 of the proximal and distal ends of the stent. By altering the tautness of the sutures, the size of - 10 the stent lumen 36, the stent diameter 86, and the stent perimeters 34, can be adjusted. As can be seen, distal perimeter suture 32 runs along the stent distal end 33, whereas proximal perimeter suture 30 runs along the stent proximal end 5 31. The respective sutures run through hole 28 of each bend 22. With respect to FIGs. 4 and 5, the valve material 38 is shown, in this exemplary embodiment, as a sheet. In so constructing the valve 41, the valve material 38 is draped o across the stent lumen 36 opening (such as shown on the proximal portion of the stent) and then pushed down into the stent lumen 36 itself. Excess material can be kept outside the stent, which will later become a potential fold-over 42. However, the excess material can also be trimmed off. The valve 5 material 38 is connected to the stent, using for example, distal valve-stent suture 40. However, any well known ways to connect the valve to the stent is contemplated, such as but not limited to, sutures, adhesives, folds, or the like. In one embodiment shown in FIG. 5, the valve-stent suture 40 can share 0 the hole 28 with distal suture 32 near the stent perimeter 34. The valve material 38 can be any biocompatible material such as polyethylene terephalate(PET), polypropylene(PP), polytetrafluorethylene(PTFE), or any polymer or derivative thereof, and also includes commercially known materials such as !5 GORE-TEX, DACRON, or any other synthetic material. The preferred material 38 will be advantageously compliant and employed so as to permit effective value function as described herein and in the case of collapsible/expandable state devices will retain integrity and function when cycled between these 30 states. It is preferred to use a biomaterial that serves as a biocompatible scaffold with the ability to remodel host tissue. Accordingly, a naturally occurring biomaterial is highly desirable. One such biomaterial is collagen and more - 11 particularly, a collagen based biomaterial called extracellular matrix (ECM). Examples of ECM's include pericardium, stomach submucosa, liver basement membrane, urinary bladder submucosa, tissue mucosa, dura mater, and small intestine submucosa One 5 such biomaterial is the ECM, such as submucosa, and more particularly is small intestine submucosa (SIS). SIS can be made in the fashion described in Badylak et al., US Patent 4,902,508; Intestinal Collagen Layer described in US Patent 5,733,337 to Carr and in 17 Nature Biotechnology 1083 (Nov. 0 1999); Cook et al., WIPO Publication WO 98/22158, dated 28 May 1998, which is the published application of PCT/US97/14855; Gastric Submucosa as described in WO 98/26291 (PCT/US97/22729), claiming priority to US Provisional application 60/032,686; Liver tissue as described in WO 98/25637 (PCT/US97/22727), 5 claiming priority to 60/032,680; Stomach Submucosa as described in WO 98/25636 (PCT/US97/23010), claiming priority to 60/032,683; and Urinary Bladder Submucosa as described in US Patent 5,554,389; all the disclosures of which are hereby expressly incorporated by reference. Irrespective of the 0 origin of the valve material (synthetic versus naturally occurring), the valve material can be made thicker by making multilaminate constructs, for example SIS constructs as described in US Patents 5,968,096; 5,955,110; 5,885,619; and 5,711,969; the disclosures of which are entirely and expressly 25 incorporated by reference. With respect to FIGs. 6A and 6B, shown is the connection of the valve to the stent frame. As described above, the valve can be sutured at the distal portion of the stent using distal valve-stent suture 40. Similarly, the proximal portion of the 30 valve can be sutured to proximal portion of the stent, and more particularly to proximal perimeter suture 30. Shown is the valve connected to the proximal portion of the stent at proximal valve-stent suture 44. Suture 44 can be through a bend 22 or can attach to the proximal perimeter suture 30. In a - 12 traditional Gianturco Z-stent, it is either an 8 (bend) point or 10 (bend) point stent, so one leaflet of the valve can be sutured to the four points of an 8 point stent thereby comprising one half of the stent. To provide further integrity, 5 the valve can be sutured at the proximal and distal end to the perimeter sutures themselves, without actually being sutured to any or all of the stent bends 22. With respect to FIG. 6B, shown is the valve with the stent frame removed. Once the sutures are generally in place, the ) valve sheet 38 will form a valve pocket 46, extending inside the stent lumen in which the fluid will fill. Proximal valve perimeter 48 will have the sutures connecting the valve to the stent (not shown). Once the distal sutures are in place, the general shape will likely resemble a pocket with the pocket 5 having a valve apex 50. There is a part of the valve that will form central valve portion 49 that is not directly sutured to the stent. This valve portion 49 will form the valve opening 52 through which fluid will pass. Thus, upon filling of the valve pocket 46, the fluid pressure will exert outwards causing ) valve portion 49 to extend outward. When it does, it will contact the other leaflets or cusps and form a seal to stop or impede fluid flow. FIG. 7 shows a top view of the stent valve. In this particular non-limiting view, shown is the valve opening 52 in 5 a slightly open configuration. Valve pockets 46 are shown in a slightly distended configuration. The valve is connected, for example, by sutures to the stent perimeter 34 and also forms a valve perimeter 48. Because of the opening and closing of the valve, there may be increased wear and tear at the valve-stent o opening connection. At this point, one embodiment of the present invention provides a reinforcement at this point. For example, this reinforcement can be a plurality of reinforcement sutures 54, adhesive, another material, or any other mechanism that permits increased structural integrity.

- 13 FIG. 8 demonstrates a view of the stent valve once the distal portion of the valve is sewn to a distal bend 22 and also shows the proximal portion of the valve being connected to the proximal portion of the frame with one suture in the 5 foreground, one suture in the background. In addition, the reinforcement suture 54 is found in the foreground. Although only two sutures 44 are seen at the proximal portion, it is of course well-understood that some or each of the proximal bend of the frame can be connected to the proximal portion of the ) valve. Similarly, although only one distal suture 40 is shown, there may be as many distal sutures necessary to connect the valve apex 50 or the distal portion of the valve to the frame. It is well understood that this may be just one distal suture or many distal sutures. Varying the number of distal sutures 5 will vary the shape, tightness, and overall configuration of the valve, valve pocket 46, and the valve apex 50. The valve opening 52 although already described above, is actually created in the final step of preparation of the preferred device manufacture. The construction mentioned above ) would be repeated on the other side of the valve to create the valve pocket 46, valve apex 50, and the like on the other side. At this point, though, there is no valve opening 52. The valve opening 52 is created by creating a slit in the sheet to create the opening. The slit can be sized according to the intended 5 flow rate of the passing fluid. Accordingly, a large slit would create a large valve opening or orifice and permits a large volume of fluid to pass therethrough. The slit can be created by poking a scalpel through it and running it to the desired length. However, due to potential fatigue at the 0 orifice, another set of reinforcements may be added to the orifice perimeter. Therefore, as shown in FIGs. 7 and 8, an orifice reinforcement 53 may be created by any known conventional ways, such as sutures (resorbable or non resorbable), adhesive, string, staples, rings, or the like.

- 14 Therefore, the stent valve as constructed can be using one stent with the valve material enclosed therein. Of course in the single stent configuration, the overall length can be adjusted by elongating the length of the struts 24. However, 5 devices of the invention can be built using a plurality of stents to elongate the overall size of the stent, if desired. In this regard, it will be preferred that the length of the device 20 is sufficient to provide an aspect ratio (length to expanded diameter) sufficiently high to facilitate proper ) alignment of the device 20 within the vessel, with the axis of the device lumen generally aligned with the axis of the vessel. For example, devices having a ratio of length:expanded diameter of 1:1 or greater, or about 2:1 or greater, will be preferred. It will be understood that while such dimensions 5 will advantageously facilitate placement of the inventive devices, they are not necessary to the broader aspects of the invention. With reference to FIG. 15, shown is a double stent structure with the valve. Returning now to FIG. 9, shown is a ) first stent 58 and a second stent 60. For the purposes of discussion only, first stent 58 is shown to be atop of the second stent 60. Ultimately as shown herein by way of example only, the valve will reside in the first stent 58. It should be noted however that the valve can reside in the second stent !5 60 also as shown in FIG. 17. Furthermore, the overall length can be increased by joining several stent valves together as shown in FIGs. 18 and 19, thereby having a plurality of stents, such as a first stent 58, second stent 60, and a third stent 61. The valve 41 can be placed in any or all stents, in any 0 combination, for example, as shown by the dotted lines. In this regard, it is suggested and intended that many stents can be joined and that each or any stent may house a valve or plurality of valves. One benefit of having a plurality of stents is that upon ejection of the placement device, the - 15 invention will provide a self-aligning feature in the vessel. This is because the plurality of stents is generally longer with respect to the stent diameter, or the plurality of valve device(s), as discussed above. 5 Manufacture of the multi-stent or multi-valve device will generally follow the same construction as described above. The same considerations in making a single valve single stent device applies equally to the elongated device. Returning now to FIGs. 9 and 10, shown are methods of 0 connecting the first stent 58 and second stent 60. Equally, the construction shown from now on also includes construction of at least two stents or at least two valves. First stent 58 and second stent 60 has bends 22 that are adjacent each other. Shown in FIG. 9 is where the first stent 58 has its bends 5 beside the bends of the second stent 60 such that they are not touching each other (although they may touch). They are connected together in the manner described above, and for example by stent-stent suture 56. Stent-stent suture 56 can be resorbable or non-resorbable. This suture travels through the o distal bends of the first stent 56 and the proximal bends of the second stent 60. The suturing pattern can be that described in FIG. 2B and the accompanying discussion. As shown in FIG. 10, the bends can be juxtaposed over each other to provide an overlap such that the stent-stent suture 56 will go 25 through the bends at the same time. Therefore, the construction contemplates that the stent bends may touch, overlap, or not at all. FIG. 11 shows one embodiment of the present invention in which the valve apex 50 is sutured to at least three bends: two 30 bends of the first stent 56 and one bend of the second stent 60. In this regard, the valve also operates to keep the first stent 56 partially connected to the second stent 60. From the bends, a plurality of valve apex sutures 66 are seen. These sutures can emanate from the bends and each bend can have many - 16 valve apex sutures 66 that travel in many directions. Using multiple valve apex sutures 66 that emanate in many directions and using a plurality of bends (from either stent), generally functions to minimize any parachuting or inversion of the valve 5 pocket 46. FIG. 12 demonstrates a top view of the multi-stent device in which the valve opening 52 is seen (in a closed position) and the valve pocket 46 and valve apex 50 is connected to three bends. Again it should be understood that many sutures may D emanate from many bends from any stent. As described earlier, the excess material can either be trimmed off or folded over the outer surface of the device. Shown in FIGs. 13A and 13B, is the excess material being folded over the device and attached at the distal end of the first 5 stent 58. Shown in dotted lines is the first stent 58. FIG. 13B shows that the fold-over 42 provides a second material outer sheath so that the suture passes through the inside and outside material to increase structural integrity. Also, by folding over the excess material, a smoother surface is D presented rather than the naked frame of the tip of the bend. In all embodiments of the invention, the external surface of the frame can be covered with a sheath that is not necessarily the same material as the valve 41. For example, while the valve can be a naturally occurring material, the .5 outer sheath can be synthetic material such as described herein. The sheath, therefore, can be the fold-over of the valve material, another type of naturally occurring material, or a synthetic material. Accordingly, the sheath may partially or totally cover the frame. 0 FIG. 14 shows an embodiment in which both the first stent 58 and second stent 60 are covered by the fold over 42. Here, the fold-over 42 is connected to the distal portion of the second stent 60. In this manner, the entire device may be covered with an outer sheath of biomaterial. The benefit of - 17 doing so, especially if using SIS or other similar ECMs, is that the regrowth and endothelialization of the device embeds and encapsulates the frame. Accordingly, there is a reduced risk of device migration. Furthermore, due to the remarkable 5 remodeling properties of SIS, the outer SIS sheath acts as a conduit for host tissue to infiltrate the device and remodel the valve itself. Over the course of months, the valves are replaced by host tissue and the SIS disappears. FIG. 15 shows yet another embodiment of the present 3 invention. In this demonstration, the valve is located in the first stent 58, sutured at the proximal end at the stent perimeter. The valve apex 50 is sewn somewhat proximal of the stent-stent suture 56. The valve apex 50 is sewn at the valve apex sutures 66 to an intermediate portion of the frame. To 5 minimize parachuting or inversion, a valve intermediate portion 75 may be sutured using valve intermediate suture 76 to connect the valve to the frame. In addition, the valve may be so constructed to extend the valve's length to create an elongated valve pocket 90 (shown by the dotted lines). While the ) extended pocket 90 can be connected to the distal perimeter of the second stent distal suture 62, it can also be connected to an intermediate portion of the second stent. With further reference to FIG. 15, it is seen that the valve opening 52 is a slit that extends across the first stent 5 diameter 21 but terminates several millimeters before reaching the edge. In some embodiments, this distance could be 1-5 mm from the edge. Of course, it is understood that the invention contemplates any distance that varies the length of the slit. Also, shown in FIG. 15, but equally applies to any device 0 described herein, is an anchor 92, which can be anchor barbs 92. These barbs 92 can dig into the adjacent vessel wall to relatively affix the device at its location. Anchor 92, although shown as barbs, may include hooks, adhesives, knobs, a textured surface, or any other treated surface that facilitates - 18 relative affixation of the device in its location. Similarly, the outer surface of the fold-over or sheath can be so configured to provide anchoring. FIG. 16 demonstrates the device upon implantation into the 5 patient. Upon implantation the device generally resides in a vessel 80. For example, the vessel could be vein, artery or the heart or wherever a valve is necessary. In one preferred use, the vessel is an incompetent vein in the leg or foot of a patient. The device 20 reduces or prevents retrograde blood ) flow, while normal blood flow is permitted to travel through device 20. Illustrative veins in which the device 20 may be used include, for example, saphenous veins, femoral veins, popliteal veins, tibial veins, and the inferior vena cava. The vessel 80 has an inner lumenal surface 82 in which 5 the fluid flows. The fluid flow path is shown as fluid path 70. Vessel 80 also has a vessel diameter 84. The medical device, upon implantation, will also have a device outer stent diameter 86. The outer diameter 86 will be chosen to permit contact with the inner lumenal surface 82. The optimized fit 3 will decrease the leakage around the device by contacting the inner lumenal surface 82. A tight fit can be accomplished by sizing the stent diameter to be greater than the vessel diameter. For example, a stent diameter that is about 110 percent greater than (i.e. 1.1 times) the vessel diameter 5 provides a good fit. Expanded stent diameters of about 10 mm to about 30 mm will be typical in many applications of the present invention. Again, while it is shown in this FIG. 16 that the valve is located in the first stent 58 and only the first stent 58 is covered by the fold-over 42 or sheath, it 0 should be remembered that the valve could be located in the second stent 60. Similarly, the fold-over 42 or sheath could extend onto the second stent 60. The standard method of deploying the medical device 20 in a vessel 80 involves the use of a medical assembly (see FIG.

- 19 20) including the device 20 and a delivery device such as a percutaneous delivery device, e.g. a catheter 100. The frame is configured to a contracted state, e.g. by resiliently forming the frame into a contracted configuration, to load into 5 the delivery device (catheter). The catheter can be introduced into the patient via a suitable approach, for example through the jugular or femoral vein. To advance and deploy the device from the distal end of the delivery catheter, a pusher 101 is placed into the catheter lumen. When the device 20 is fully D deployed, it assumes the second, expanded configuration within the vessel 80 as depicted in FIG. 16. The stent frame, being made of resilient material, conforms to the shape of the vessel wall such that when viewed on end, the device 20 has a circular appearance when deployed in a round vessel. 5 FIGs. 17, 18, and 19 show other described embodiments. FIG. 17 demonstrates the valve 41 in the second stent 60. In this embodiment, the valve apex 50 is connected to the second stent's distal perimeter. FIG. 18 demonstrates at least two stent frames connected together. In this particular 0 embodiment, the valve is located in the first stent 58, with the valve apex 50 being connected at the first stent 58-second stent 60 junction. In dotted lines, however, there may be many stents, such as first stent 58, second stent 60, and third stent 61. The valve 41 may be found in any of the stents or in .5 all. Similarly, in the three stent configuration, the valve may begin at the first stent and have the valve apex 50 be generally located in the third stent 61. FIG. 19 shows another embodiment of the present invention in which the valve 41 begins in the second stent 60 and extends into the third stent ) 61 thereby having the first stent 58 being empty. Finally, since the device is located in an in vivo environment, the device may be treated with therapeutic agents to facilitate healing. For example, the frame may be treated with therapeutic agents such as anti-cancer drugs, plaque - 20 busters, anti-coagulants, or the like. Similarly, the valve material can be treated with therapeutics agents such as anti cancer drugs, plaque busters, anti-coagulants, proteins, growth factors, proteoglycans, and the like. Furthermore, radiopaque 5 agents may be added, such as tantalum, barium, bismuth, or the like to increase radiopacity. These ingredients can be bonded to the frame or the valve material such as rubbing the agent in, bonding it, adhering it, or the like. While the invention has been illustrated and described in 3 detail in the drawings and the foregoing text, it is understood that these are only some embodiments and that the scope of the invention is not solely defined by the description herein but also by the appended claims. All modifications and changes that come within the spirit of the invention are hereby 5 protected. Throughout this specification and the claims which follow, unless the context requires otherwise, the word "comprise", and variations such as "comprises" and "comprising", will be understood to imply the inclusion of a D stated integer or group of integers or steps but not the exclusion of any other integer or step or group integers or steps. The reference in this specification to any prior publication (or information derived from it), or to any matter !5 which is known, is not, and should not be taken as an acknowledgment or admission or any form of suggestion that that prior publication (or information derived from it) or known matter forms part of the common general knowledge in the field of endeavour to which this specification relates. H0 The disclosure of the complete specification of Australian Patent Application Nos. 2006218278 and 33166/01 as originally filed is incorporated herein by reference.

Claims

1. A percutaneously-implantable vascular valve device, comprising: 5 a percutaneously-implantable frame having a proximal frame end, and a distal frame end; and a plurality of attached structures separately fabricated from but attached to the frame, each attached structure comprising a hole defined completely through the attached 3 structure; at least two valve leaflets comprising flexible biomaterial and located at least partially within the frame when the frame is in an expanded configuration, the at least two flexible valve leaflets forming a valve opening occurring 5 between upper portions of the leaflets, and wherein the leaflets are supported on the frame at least in part via the attached structures; and a mechanism inward of the frame and holding together the upper portions of the flexible biomaterial of adjacent leaflets ) defining the valve opening.

2. The vascular valve device of claim 1, wherein the flexible biomaterial is pericardium, and wherein the valve device has three leaflets. 5

3. The vascular valve device of claim 1 or claim 2, wherein the mechanism comprises sutures connecting upper portions of the flexible biomaterial of adjacent leaflets. 0

4. The vascular valve device of any one of claims 1 to 3, wherein the outer surface of the frame is completely or partially covered with a sheath. - 22

5. The vascular valve device of claim 4, wherein the outer surface of the frame is partially covered with a sheath.

6. The vascular valve device of claim 4 or claim 5, 5 wherein the sheath comprises a synthetic material.

7. The vascular valve device of claim 6, wherein the synthetic material comprises a synthetic polymer material.

8. The vascular valve device of any one of claims 4 to 7, wherein the sheath is configured to provide anchoring of the vascular valve device upon implantation.

9. The vascular valve device of any one of claims 1 to 5 8, wherein the implantable frame has an aspect ratio of at least 1:1.

10. The vascular valve device of any one of claims 1 to 9, wherein a distal end of the valve is connected to a distal ) end of the frame.

11. The vascular valve device of any one of claims 1 to 10, wherein the frame is provided by a single stent. 5

12. The vascular valve device of any one of claims 1 to 10, wherein the frame is provided by a plurality of stents.

13. The vascular valve device of claim 11, wherein the stent is a self-expanding stent. - 23

14. The vascular valve device of claim 11, wherein the stent is a non-self-expanding stent. 5

15. The vascular valve device of claim 12, wherein the stents are self-expanding stents.

16. The vascular valve device of claim 12, wherein the stents are non-self-expanding stents.

17. A percutaneously-implantable vascular valve device, comprising: a percutaneously implantable frame having a proximal frame end and a distal frame end; 5 a plurality of attached structures separately fabricated from but attached to the frame, each attached structure comprising a hole defined completely through the attached structure; at least two valve leaflets comprising pericardium and 3 located at least partially within the frame when the frame is in an expanded configuration, the at least two flexible valve leaflets forming a valve opening occurring between upper portions of the leaflets, wherein the leaflets are supported on the frame at least in part via the attached structures; 5 a mechanism inward of the frame and holding together the upper portions of the adjacent leaflets defining the valve opening; and a sheath comprised of synthetic material partially covering an outer surface of the percutaneously implantable o frame.

18. The vascular valve device of claim 17, wherein the valve device has three leaflets comprising pericardium. - 24

19. The vascular valve device of claim 17 or 18, wherein the synthetic material comprises a synthetic polymer material.

20. The vascular valve device of any one of claims 17 to 5 19, wherein the sheath is configured to provide anchoring of the vascular valve device upon implantation.

21. The vascular valve device of any one of claims 17 to 20, wherein the implantable frame has an aspect ratio of at ?3 least 1:1.

22. The vascular valve device of any one of claims 17 to 21, wherein a distal end of the valve is connected to a distal end of the frame. 5

23. The vascular valve device of any one of claims 17 to 22, wherein the frame is provided by a single stent.

24. The vascular valve device of any one of claims 17 to D 22, wherein the frame is provided by a plurality of stents.

25. The vascular valve device of claim 23, wherein the stent is a self-expanding stent. 5

26. The vascular valve device of claim 23, wherein the stent is a non-self expanding stent.

27. The vascular valve device of claim 24, wherein the stents are self-expanding stents. ~0

28. The vascular valve device of claim 24, wherein the stents are non-self expanding stents. - 25

29. A medical assembly, comprising a vascular valve device of any one of claims 1 to 16, and a catheter in which said vascular valve device is received. 5

30. A medical assembly, comprising a vascular valve device of any one of claims 17 to 28, and a catheter in which said vascular valve device is received.