Source: http://www.google.com/patents/US20100286768?dq=7222078
Timestamp: 2017-10-18 03:56:50
Document Index: 62053393

Matched Legal Cases: ['arts 110', 'art 110', 'art 110', 'art 110', 'art 110', 'arts 110', 'art 110', 'art 20', 'art 20', 'art 20', 'art 20', 'art 20', 'art 20', 'art 20', 'art 20', 'art 20', 'art 20', 'art 20', 'art 20', 'art 20', 'art 110', 'art 20', 'art 20', 'art 20']

Patent US20100286768 - Delivery and retrieval systems for collapsible/expandable prosthetic heart ... - Google Patents
A system for delivering a collapsible and re-expandable prosthetic heart valve into a patient includes a valve support structure (140) around which the valve (10) is disposed in a collapsed condition. A sheath structure (110) surrounds the collapsed valve, but can be moved relative to the valve to uncover...http://www.google.com/patents/US20100286768?utm_source=gb-gplus-sharePatent US20100286768 - Delivery and retrieval systems for collapsible/expandable prosthetic heart valves
Publication number US20100286768 A1
Application number US 12/735,273
PCT number PCT/US2009/000104
Also published as EP2240121A1, US9180004, US20150374492, WO2009091509A1
Publication number 12735273, 735273, PCT/2009/104, PCT/US/2009/000104, PCT/US/2009/00104, PCT/US/9/000104, PCT/US/9/00104, PCT/US2009/000104, PCT/US2009/00104, PCT/US2009000104, PCT/US200900104, PCT/US9/000104, PCT/US9/00104, PCT/US9000104, PCT/US900104, US 2010/0286768 A1, US 2010/286768 A1, US 20100286768 A1, US 20100286768A1, US 2010286768 A1, US 2010286768A1, US-A1-20100286768, US-A1-2010286768, US2010/0286768A1, US2010/286768A1, US20100286768 A1, US20100286768A1, US2010286768 A1, US2010286768A1
Patent Citations (14), Referenced by (117), Classifications (9), Legal Events (2)
US 20100286768 A1
16. The apparatus defined in claim 14
wherein the valve support structure includes elements that extend radially outwardly into a tubular geometric shape in which a frame structure of the collapsed valve is disposed, said elements being positioned to interfere with motion of the valve, parallel to a longitudinal axis of the tubular geometric shape, relative to the valve support structure.
This invention relates to prosthetic heart valves. More particularly, the invention relates to prosthetic heart valves that can be collapsed to a relatively small circumferential size for delivery into a patient's body with reduced invasiveness to the patient, and which can then be re-expanded to operating size at the intended implant site in the patient. Still more particularly, the invention relates to methods and apparatus for delivering a valve of the type described above into a patient and re-expanding the valve at the implant site. Another possible aspect of the invention relates to methods and apparatus for repositioning the valve in the patient and/or for retrieving the valve from the patient if desired.
The present invention will be shown and described herein primarily in the context of prosthetic aortic valves. It will be understood that the invention can also be applied to prostheses for other valves in the heart. The invention will sometimes be referred to herein in the context of introducing a replacement (prosthetic) aortic valve into a patient's heart via the left ventricle at the apex (lower extremity) of the patient's heart. From such an apical access point, the valve is moved upward to the vicinity of the annulus of the patient's native aortic valve, where the replacement heart valve is released from the delivery apparatus and thereby implanted in the patient. (The word “upward” and other similar terms are used as though the patient were standing, although the patient will of course not be standing during a heart valve replacement procedure.) It will be understood that this (exemplary) implant site can be approached in other ways (e.g., percutaneous transluminal, transaortic, transfemoral, or using any incision along the length of the ascending or descending aorta).
The delivery apparatus and methods of this invention may allow the prosthetic heart valve to be delivered and released in different ways. For example, a construction of the delivery apparatus may allow different parts of the replacement heart valve to be released before other parts are released, and the delivery apparatus may allow the order in which different parts of the valve are released to be varied in different situations. In all cases the word proximal is used to refer to the part of the valve or the part of the valve delivery apparatus that is closer to the operator (medical practitioner) of the apparatus. The word distal is used to refer to the part of valve or apparatus that is farther from the operator. The delivery apparatus may allow the distal part of the valve to be released from that apparatus before or after the proximal part of the valve is released. Also, the orientation of the valve in the delivery apparatus may be different in different situations. In some cases the part of the valve that will be upstream in the patient's blood flow when the valve is implanted may be located proximally in the delivery apparatus. In other cases the part of the valve that will be downstream in the patient's blood flow when the valve is implanted may be located proximally in the delivery apparatus. Various combinations of the foregoing options are possible, so that, for example, the portion of the valve that is released from the delivery apparatus first may be (1) proximal and downstream, (2) distal and downstream, (3) proximal and upstream, or (4) distal and upstream.
FIG. 1 shows an illustrative embodiment of the distal portion of prosthetic valve delivery apparatus 100 in accordance with the invention. FIG. 1 shows apparatus 100 containing a prosthetic aortic heart valve 10 prior to deployment of that valve. Valve 10 is visible in apparatus 100 because an outer, hollow, tubular sheath 110 a-b of apparatus 100 is shown as though substantially transparent, although sheath 110 a-b could in fact be opaque. Only the distal portion of delivery apparatus 100 is shown in FIG. 1. It will be understood that apparatus 100 continues in the proximal direction (downward and to the left as viewed in FIG. 1), ultimately extending to operator controls, which can be used by an operator (medical practitioner) to (remotely) control the distal portion of the apparatus that is visible in FIG. 1. Whereas the distal portion of apparatus 100 typically enters the patient's body by any of several different routes, the proximal controls tend to remain outside the patient's body where they can be manipulated by the operator.
Principal components of valve 10 are relatively stiff frame 20 and flexible leaflets 30. Because valve 10 is inside delivery apparatus 100, valve 10 is shown in its undeployed, circumferentially relatively small (collapsed) condition. Frame 20 includes three major portions: (1) upstream (blood in-flow side) hollow annular portion 20 a, (2) downstream (blood out-flow side) hollow annular portion 20 c, and (3) an annular array of axially extending struts 20 b that extend between and connect upstream and downstream portions 20 a and 20 c. When released from apparatus 100, upstream portion 20 a annularly expands in the vicinity of the patient's native aortic valve annulus to engage the patient's native tissue in that vicinity. Similarly, when released from apparatus 100, downstream portion 20 c annularly expands in the patient's aorta downstream from the valsalva sinus and engages that tissue of the aorta. Further, when valve 10 is released from apparatus 100, struts 20 b pass through the patient's valsalva sinus so that these struts continue to link the other portions 20 a and 20 c of the frame.
The flexible leaflets 30 of the valve 10 are mounted on upstream frame portion 20 a so that they are at least primarily inside that frame portion.
The distal portion 110 b of a split outer sheath of apparatus 100 is securely attached to tip 130 and extends proximally therefrom to sheath split or parting line 110 c. In particular, parting line 110 c is annular and located in the vicinity of the strut portion 20 b of valve frame 20. Parting line 110 c is at the location where the proximal end of distal sheath portion 110 b meets the distal end of proximal sheath portion 110 a, and where these two portions of the sheath can be pulled apart when desired. The adjacent ends of these two sheath portions 110 a and 110 b may initially abut one another at parting line 110 c, or they may initially axially overlap one another in the vicinity of parting line 110 c. (As used herein, the term axially or the like means parallel to the longitudinal axis of apparatus 100.) From the foregoing it will be seen that when inner-most shaft 132 is moved axially, the entire subassembly of shaft 132, sheath portion 110 b, and tip 130 moves together as a unit.
Annularly around the (invisible in FIG. 1) central-most shaft 132 on which tip 130 is mounted is another axially extending longitudinal shaft 120. Shaft 120 is axially movable relative to the above-mentioned central-most shaft. An annular plunger 140 is securely mounted on the distal end of shaft 120. Plunger 140 includes (1) a distal section 140 a having a relatively large outer diameter; (2) a proximal section 140 c having an outer diameter that alternates between relatively large and relatively small as one proceeds in the annular direction around that section of the plunger; and (3) an intermediate section having a relatively small outer diameter. The above-mentioned relatively large diameters fit with only a relatively small clearance inside sheath 110 b. The above-mentioned relatively small diameters are small enough to readily accept the thickness of valve frame 20 between the plunger surface having such relatively small diameter and the inner surface of sheath 110 b. Intermediate portion 140 b is axially long enough to relatively snugly receive the axial length of the distal portion 20 c of valve frame 20. Similarly, struts 20 b of valve frame 20 can pass axially through the reduced-diameter regions of the proximal portion 140 c of plunger 140.
From the above description it will be appreciated that the distal portion 20 c of valve frame 20 is captured radially between the outer surface of the intermediate portion 140 b of plunger 140 and the inner surface of the distal sheath portion 110 b, and that it is captured axially between the distal portion 140 a of plunger 140 and the relatively large diameter portions of the proximal portion 140 c of the plunger. There is even rotational securement of valve frame 20 relative to plunger 140 as a result of struts 20 b passing through proximal plunger portion 140 c between relatively large diameter regions of that proximal portion.
Proximal of valve 10 is another plunger 150 securely mounted to shaft 120 and coaxial (annular) around that shaft. Proximal plunger 150 has a relatively large outer diameter that fits within proximal sheath portion 110 a with relatively small clearance.
FIG. 2 shows one example of how the FIG. 1 apparatus may be operated to begin to deploy valve 10 in a patient. In this example, when valve 10 is at the intended implant site in the patient, proximal sheath 110 a is pulled back proximally relative to everything else in FIG. 2. This begins to expose the proximal portions of valve 10. However, the distal portions of valve 10 remain securely held by the distal portions of delivery apparatus 100. This manipulation of delivery apparatus 100 can continue until (as shown in FIGS. 3 and 4) the entire proximal portion of valve 10 has been exposed. FIG. 3 shows this result in simplified form, which omits depiction of the consequent radial enlargement of the proximal portion of valve 10. However, FIG. 4 does show the proximal portion 20 a of valve 10 enlarging radially outward as a result of its release from constraint by proximal sheath 110 a. (All of the enlargement of the valve depicted and/or described herein may be due to resilient and/or shape-memory enlargement of valve frame 20. Shape-memory enlargement may be partially controlled by controlling the ambient temperature that valve frame 20 is exposed to.)
FIG. 5 shows further deployment of valve 10 (after the condition shown in FIGS. 3 and 4 has been reached). (Again, FIG. 5 is simplified by not showing the radial enlargement of the proximal portion of valve 10.) In FIGS. 5 tip 130 is pushed distally relative to other structure in the FIG. by pushing the shaft 132 (on which tip 130 is mounted) distally relative to shaft 120. (Shaft 132 was mentioned earlier, but it was not visible in the FIGS. prior to FIG. 5.) As tip 130 moves distally, it carries distal sheath portion 110 b with it, thereby beginning to expose the distal portion of valve 10, which distal valve portion (at least initially) continues to be held securely by plunger 140 inside distal sheath portion 110 b.
FIG. 6 shows the condition of the FIG. 5 apparatus after distal sheath 110 b has moved completely beyond the distal end of valve 10 and the valve is therefore completely exposed and deployed in the patient (except that FIG. 6 again omits the fact that at this stage valve 10 will have annularly enlarged along its entire length to engage surrounding native body tissue of the patient, thereby anchoring the valve at the desired implant site in the patient). After valve 10 has thus annularly enlarged and deployed in the patient, the valve delivery apparatus 100 can be withdrawn from the patient. To facilitate such withdrawal, proximal sheath portion 110 a can be pushed distally relative to other components through the leaflet structure 30 of the valve. Distal tip 130 and distal sheath portion 110 b can then be pulled proximally relative to other components until the proximal end of sheath 110 b meets the distal end of sheath 110 a (or, as in other embodiments, until distal sheath portion 110 b is inside proximal sheath portion 110 a), thereby again giving delivery apparatus 100 a smooth outer surface. This facilitates withdrawal of apparatus 100 in the proximal direction through deployed valve 10 without compromising leaflets 30.
FIG. 7 shows two possible variations from earlier-described embodiments. (The general reference number 100 continues to be used for the delivery apparatus, even though there are some variations from earlier embodiments.) One of these possible variations is use of proximal end retainer 150 so that the proximal end of valve 10 can rest on it, thereby controlling the collapsed inside diameter of the valve. The other possible variation is relocating the split 110 c between the proximal sheath portion 110 a and the distal sheath portion 110 b so that split 110 c is proximal of valve 10. The valve is now deployed solely by moving distal sheath portion 110 b distally to a final position like that shown in FIG. 8. In other words, moving distal sheath portion 110 b (which initially completely covers valve 10) in the distal direction completely uncovers the valve for deployment in the patient. (FIG. 8 again omits depiction of the annular enlargement of valve 10 that follows from moving sheath 110 b away to expose the valve.)
Returning to embodiments like those shown in FIGS. 1-6, FIG. 9 shows a possible alternate use. This alternate use is deployment of the distal portion 20 c first. This is accomplished by shifting elements 130, 132, and 110 b distally relative to other components before shifting sheath portion 110 a proximally. This is the condition of the apparatus that is shown in FIG. 9; and as that FIG. shows, it results in release and annular enlargement of the distal portion 20 c of valve 10, while the proximal portion 20 a is still confined within proximal sheath portion 110 a. The condition shown in FIG. 9 will be followed by shifting sheath portion 110 a proximally, which exposes and deploys (i.e., allows annular enlargement of) the proximal portion 20 a of valve 10.
FIGS. 11 and 12 show some possible ways that the parts 110 a and 110 b of an axially split sheath 110 may come together. In FIG. 11 a distal portion of part 110 a is slightly enlarged so that it can fit around the outside of the proximal portion of part 110 b. In the alternative shown in FIG. 12 this arrangement is reversed. In particular, in FIG. 12 the proximal portion of part 110 b is slightly enlarged so that it can fit around the outside of the distal portion of part 110 a. Other variations are possible, such as having the ends of parts 110 a and 110 b the same size so that they simply abut one another with no overlapping (as they do in FIGS. 11 and 12).
FIG. 15 shows an alternate design in which a “bumper” 140′ or 150′ is mounted on shaft 120 adjacent each axial end of the frame 20 of valve 10. Each bumper has a face that is perpendicular to the longitudinal axis of the apparatus and that faces toward the axial end of valve frame 20 that is adjacent to that bumper. These bumper faces keep valve 10 trapped at the desired axial location in the delivery apparatus until the valve is exposed and therefore able to annularly enlarge as a result of the axial shifting of sheath portions 110 a and 110 b. The faces of bumpers 140′ and 150′ that face away from valve 10 are preferably conical as shown. This helps sheath portions 110 a and 110 b to again come together after valve deployment, when a smooth exterior of apparatus 100 is again desired to facilitate withdrawal of the delivery apparatus from the patient.
FIGS. 16-18 illustrate another possible construction of delivery apparatus 100. In this construction proximal sheath part 110 a initially extends distally all the way to distal tip 130. Inside the distal portion of sheath 110 a, distal sheath portion 110 b extends proximally from distal tip 130 to initially completely cover valve 10 (i.e., it ends with some overlap of the distal part of plunger 150). Valve 10 is deployed by first pulling sheath 110 a back proximally so that its distal end is adjacent plunger 150 as shown in FIG. 17. No part of the valve is yet deployed, however, because the valve is still entirely inside sheath 110 b. Then distal tip 130 and sheath 110 b can be pushed distally to begin to expose valve 10 as shown in FIG. 18. This exposure of the valve starts at the proximal end (as shown in FIG. 18), and then continues until the valve is completely exposed and deployed. (Once again, FIG. 18 omits depiction of the annular enlargement of valve 10 that occurs when the valve is exposed.)
A possible variation of what is shown in FIGS. 16-18 is to make distal sheath 110 b shorter so that the proximal end of the valve begins to deploy when the proximal sheath 110 a is retracted beyond the proximal end of distal sheath 110 b.
FIG. 28 shows an illustrative embodiment of structures in accordance with certain possible aspects of the invention for facilitating recollapsing of a valve 10 for such purposes as allowing the valve to be repositioned in the patient or removed from the patient after it has been at least partly deployed in the patient but before final release of the valve from the delivery apparatus. FIG. 28 shows only the distal part 20 c of the valve 10 (the other parts of the valve being omitted for clarity). As shown in FIG. 28 (and also FIG. 29), three strands 210 a-c of flexible recollapsing material are threaded through the distal part 20 c of the frame (stent) of valve 10. For example, FIG. 29 more clearly shows that each of these strands 210 is threaded through a respective one of three different arcuate segments of the annulus of distal part 20 c. Eyelets (visible in FIG. 28) may be provided in part 20 c for threading strands 210 through. Each strand may follow a woven or serpentine trajectory, alternately into and out of the interior of part 20 c, as one proceeds in the annular direction around part 20 c. The ends of each strand 210 that extend from part 20 c enter the lumen of delivery system structure 120 via radial apertures 142 through the side wall of distal retainer 140 as in FIG. 24, which distal retainer is attached to structure 120. Once inside the above-mentioned lumen, these strand ends extend along the lumen in the proximal direction to where they become accessible to control by the operator of the delivery apparatus from outside the patient's body. It is preferred that the apertures (like 142 in FIG. 24) be in approximately the same plane (substantially perpendicular to the longitudinal axis of the delivery apparatus) as the threading of strands 210 through part 20 c. In this way, when the ends of strands 210 are pulled proximally (parallel to the longitudinal axis of the delivery apparatus), the above-mentioned apertures (like 142) convert the tension in the strands to radial inward forces on part 20 c. Because these forces are radial, they have the greatest efficiency in pulling in on part 20 c and thereby re-collapsing that part (e.g., against the outer surface of component 140). Such radial inward force is also preferred because it tends to avoid axial shifting of valve 10 during any re-collapsing operation.
The number of strands 210 and/or the pattern in which they attach to part 20 c can differ from what is shown in FIGS. 28 and 29. For example, FIG. 30 shows the use of many more than three strands 210, and FIG. 30 also shows each strand having basically only one point of attachment to part 20 c. Each such point of attachment is preferably radially out from the aperture (like 142) through which the associated strand 210 enters the lumen inside structures 120/140, and each point of attachment and the associated aperture (like 142) are on an associated radius that is preferably substantially perpendicular to the longitudinal axis of the delivery apparatus.
If, after valve 10 has been partly deployed in the patient, the location of the valve does not appear (e.g., fluroscopically) to be as desired, the valve can be recollapsed back onto the delivery apparatus by pulling on the proximal ends of strands 210. The valve can then either be removed from the patient (by withdrawing the delivery apparatus from the patient), or the valve can be relocated in the patient (by manipulating the delivery apparatus to produce such relocation). Such valve removal or relocation may also include again closing the sheath structure(s) 110 a and/or 110 b around the outside of the valve. Assuming that valve relocation is the objective, when the valve is at the new location, it can be expanded again by releasing the tension on strands 210 and, if sheath 110 a and/or 110 b was re-closed around the valve, re-opening that sheath structure. When the valve is finally satisfactorily positioned in the patient, the valve can be finally released from the delivery apparatus by pulling one proximal end of each strand 210 proximally until the other end of the strand emerges out of the delivery system at the operator controls end.
Although the above valve retrieval/repositioning structure is shown applied to valve part 20 c, it will be understood that it can alternatively or additionally be applied to other valve parts such as 20 a.
Element 110 a-b is again the main outer shaft of the delivery apparatus, with part 110 a being the proximal sheath. This structure can facilitate introduction of fluids, which can be used to prep the delivery apparatus so that no gas (e.g., air) bubbles are introduced into the patient's circulatory system. Element 110 a-b can also be used as a vessel that houses saline, which keeps valve 10 hydrated from the time it is loaded into the system until it is implanted in the patient. Structure 110 a may also function as the proximal sheath, which controls/houses the crimped proximal end of the valve.
Shaft or conduit 120 controls the crimped valve's axial movement for deployment and retrieval. Structure 120 facilitates introduction of fluids through port 360 a, which aids in flushing and prepping the delivery apparatus.
Inner lumen 132 may be a hypo-tube or any other conduit that is not limited to but allows introduction of ancillary devices such as guide wires, embolic protection devices, a balloon for pre-dilation of the implant site, fluids, etc. Also, shaft 132 is the means by which the distal sheath 110 b is moved distally to release the distal end of the crimped valve. FIG. 35 shows an alternative having a valve connector 390 attached to the proximal end of inner lumen 132 (in lieu of molded handle 134 as in FIGS. 32-34). FIG. 36 shows another alternative in which manifold connectors 390, etc., can be attached to the proximal end of inner lumen 132 (again in lieu of molded handle 134). The FIG. 36 embodiment can provide a through port into the proximal end of inner lumen 132, whereby fluids and other devices of the types mentioned earlier (e.g., guide wires, embolic protection devices, balloons for pre-dilation of the implant site, etc.) can enter and pass through the entire length of the delivery apparatus (e.g., while delivery apparatus 100 is in place in the patient).
Although the foregoing tends to show valve 10 oriented in delivery apparatus 100 so that what will be the downstream portion 20 c of the valve (in terms of blood flow through the valve after it has been implanted in a patient) is toward the distal end of the delivery apparatus, it will be understood that this orientation of the valve can be reversed if desired. The valve orientation that is generally shown herein is suitable, for example, for implanting an aortic valve via an antegrade approach (i.e., delivery apparatus 100 inserted in the blood flow direction). An example of such antegrade delivery in insertion of delivery apparatus 100 through an incision in the so-called apex of the heart (e.g., near the bottom of the left ventricle) and passage of the distal portion of delivery apparatus 100 up through the left ventricle until valve 10 is positioned adjacent the patient's native aortic valve annulus, where the valve can be deployed from the delivery apparatus and thereby implanted in the patient. (This may be referred to as a transapical approach.) A typical final disposition of the valve is with the extreme lower portion of valve frame part 20 a flared out below and lodged against the native valve annulus, with the more distal portion of frame part 20 a passing tightly through the native annulus, with struts 20 b passing through the native valsalva sinus, and with valve frame part 20 c lodged tightly in the native aorta downstream from the valsalva sinus.
FIG. 37 illustrates in more detail a point made earlier regarding how valve support structure such as 140 can be constructed to cooperate with collapsed valve 10 to substantially prevent the collapsed valve from moving relative to the delivery apparatus parallel to the longitudinal axis of the valve and the delivery apparatus. FIG. 37 shows structure like that shown, for example, in FIGS. 1-10, 14, 16-18, 23, 24, 27, and 31. In particular, FIG. 37 shows a simplified, partial, sectional view of a distal portion of such structure. FIG. 37 shows that a distal portion 20 c of the frame of collapsed valve 10 is disposed in a recess in the outer surface of the distal retainer 140 portion of the valve support structure of the delivery apparatus. For reference, a geometric longitudinal axis of valve 10 and delivery apparatus 100 is shown at 101. (FIG. 37 omits depiction of the sheath or sleeve structure 110 that may be present around the outside of which is shown in FIG. 37.)
The portion of valve frame 20 that is disposed in the above-mentioned recess in valve support structure 140 has first and second surface portions 21 a and 21 b that face in respective opposite first and second directions along axis 101. Valve support structure 140 (in particular the above-mentioned recess) has third and fourth surface portions 141 a and 141 b that respectively face in the second and first directions. The first and third surface portions 21 a and 141 a are positioned adjacent to and facing one another. Similarly, the second and fourth surface portions 21 b and 141 b are positioned adjacent to and facing one another. These relationships among surfaces 21 a/b and 141 a/b substantially prevent relative movement of valve 10 and valve support structure 140 along axis 101 while the valve is disposed around the valve support structure in the collapsed condition. For example, this secure holding of the valve means that the valve can be placed where desired in the patient, and then any sheath or sleeve structure like 110 a/b can be moved relative to the valve and the valve support structure without disturbing the desired location of the valve in the patient. This may be especially important in cases in which the valve frame is resiliently biased to press outwardly against the surrounding sheath. Without secure positioning of the valve relative to its support structure, the valve might be dragged with the sheath when the sheath is shifted relative to the valve support. This could disturb the location of the valve in the patient and/or make it difficult to get the valve out of the sheath.
FIG. 38 brings out the same point (made above in connection with FIG. 37) for embodiments like those shown in FIG. 15. Thus FIG. 38 shows that the frame 20 of valve 10 is received in a recess between the distal bumper 140′ and the proximal bumper 150′ of the valve support structure. Valve frame 20 has first and second surfaces 21 a and 21 b that face in respective opposite first and second directions along axis 101. Valve support structure 120/140′/150′ has third and fourth surface portions 141 a and 151 b that respectively face in the second and first directions. The first and third surface portions 21 a and 141 a are positioned adjacent to and facing one another. Similarly, the second and fourth surface portions 21 b and 151 b are positioned adjacent to and facing one another. These relationships among surfaces 21 a/b and 141 a/151 b substantially prevent relative movement of valve 10 and valve support structure 120/140′/150′ along axis 101 while the valve is disposed around the valve support structure in the collapsed condition. For example, this secure holding of the valve means that the valve can be placed where desired in the patient, and then any sleeve structure like 110 a/b can be moved relative to the valve and the valve support structure without disturbing the desired location of the valve in the patient.
Another way to describe possible features of the invention of the type highlighted by FIGS. 37 and 38 is to say that the valve support structure has elements that extend radially out at least into a tubular geometric shape in which the frame of the collapsed valve is disposed on the valve support structure. These elements are positioned to positively interfere with and thereby prevent relative axial movement of the collapsed valve and the valve support structure. Specific examples of such outwardly projecting elements on the valve support structure are the outer portions of elements 140 a, 140 c, 140′, and 150′. These elements operate to hold the collapsed valve in a fixed axial position on the valve support structure of the delivery apparatus by contacting axially facing surfaces of the valve frame if the valve attempts to move axially relative to the support structure.
FIG. 42 illustrates yet another possible feature in accordance with the invention. This is making shaft 132 so that it can articulate (bend relatively easily) in an articulation area or location 132 a. This articulation location 132 a is preferably somewhat proximal of the proximal end of sheath portion 110 b. The purpose of this is to allow distal structures 130, 110 b, and the portion of shaft 132 that is distally beyond articulation 132 a to deflect laterally in order to somewhat follow the curvature of the patient's aortic arch when these elements are pushed distally into that arch to expose valve 10 for deployment in the vicinity of the patient's native aortic valve annulus, etc. This helps reduce resistance to distal motion of elements 130 etc. that might otherwise result from contact of the aortic arch by those elements.
Operational Steps: The delivery apparatus can be introduced from any of the previously described approaches. Once satisfactory axial and radial positioning are achieved, the deployment sequence begins. The valve can be deployed proximal-end-first or distal-end-first. In the aortic valve case (and depending on the valve's design and/or geometry), it is preferred to deploy the valve's proximal end first in order for it to flare out. In doing so, the delivery apparatus can be advanced forward slightly until resistance is felt. This tactile feedback to the operator is an indication that optimal axial alignment has been achieved as the valve's skirt is sub-annular of the native valve. While maintaining a slight pressure forward on the delivery apparatus to maintain the valve's axial position, the distal end can now be deployed by advancing the distal sheath forward. During proximal and/or distal end deployment, temperature-controlled saline can be infused to facilitate a slow, controlled deployment of a temperature-sensitive nitinol valve frame. This can prevent sudden “snap open” of the valve, which may be undesired because it may cause a dissection or other damage at the implant site. The saline temperature can be slowly increased to ultimately reach body temperature. This allows the valve to expand to its fully expanded and optimal geometry.
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Cooperative Classification A61F2/2436, A61F2/2418, A61F2/2439, A61F2/2427, A61F2002/9511
European Classification A61F2/24H4, A61F2/24H6
Free format text: ASSIGNMENT OF ASSIGNORS INTEREST;ASSIGNOR:ALKHATIB, YOUSEF F.;REEL/FRAME:024629/0613
Jun 28, 2010 XAS Not any more in us assignment database
Free format text: ASSIGNMENT OF ASSIGNORS INTEREST;ASSIGNORS:ONO, SEIGO;UCHIDA, KATSUICHI;REEL/FRAME:024629/0676