Source: https://patents.google.com/patent/JP5016667B2/en
Timestamp: 2019-12-15 19:35:45
Document Index: 793998218

Matched Legal Cases: ['Application No. 10', 'Application No. 10', 'Application No. 11', 'Application No. 11', 'application No. 11', 'Application No. 11', 'Application No. 11', 'Application No. 11']

JP5016667B2 - Multi-membered prosthetic heart valve assembly, apparatus using the same, and method of using the same - Google Patents
Multi-membered prosthetic heart valve assembly, apparatus using the same, and method of using the same Download PDF
JP5016667B2
JP5016667B2 JP2009508004A JP2009508004A JP5016667B2 JP 5016667 B2 JP5016667 B2 JP 5016667B2 JP 2009508004 A JP2009508004 A JP 2009508004A JP 2009508004 A JP2009508004 A JP 2009508004A JP 5016667 B2 JP5016667 B2 JP 5016667B2
JP2009508004A
JP2009535127A (en
ジェイムズ・ホン
タカシ・ハリー・イノ
ドネル・ダブリュー・ガースキス
マイケル・ジェイ・ドリューズ
ミミ・ヌグイェン・フィッテラー
メドトロニック，インコーポレイテッドＭｅｄｔｒｏｎｉｃ， Ｉｎｃ．
2006-04-29 Priority to US60/746,038 priority
2007-04-29 Application filed by メドトロニック，インコーポレイテッドＭｅｄｔｒｏｎｉｃ， Ｉｎｃ． filed Critical メドトロニック，インコーポレイテッドＭｅｄｔｒｏｎｉｃ， Ｉｎｃ．
2009-10-01 Publication of JP2009535127A publication Critical patent/JP2009535127A/en
2012-09-05 Publication of JP5016667B2 publication Critical patent/JP5016667B2/en
The present invention relates generally to heart valves that are implanted within a patient, and in particular, guides the assembly of multiple component heart valve assemblies that are assembled together and the components of the multi-part heart valve assembly during implantation and And / or apparatus and method for facilitating.
The prosthetic heart valve can replace a defective human valve in the patient's body. For example, one-piece prosthetic valves including sewing rings or suture cuffs have been proposed. A stitching ring or stitching cuff is attached to the outer periphery of the prosthetic valve and extends around it. Further, a multi-part artificial valve including a sewing ring separated from the valve part has been proposed. Both types of prosthetic valve suturing rings are time consuming and time consuming to secure within the target site, ie, the annulus of the heart from which the natural heart valve has been removed.
For example, to implant a suture ring within the heart's biological annulus, 12-20 sutures may first be secured to the tissue surrounding the biological annulus. Thereafter, the entire suture ring and / or prosthetic valve will advance or “parachute” down the suture toward the annulus of the body. The knots will then be tied with suture and the suture ring will be secured within the annulus of the living body where the suture will be cut. Thus, this procedure can be very complex as many suture processing and manipulations are required. The complexity of the procedure provides more opportunities for mistakes and also requires the patient to be on cardiopulmonary bypass for an extended period of time.
Because the heart's living annulus does not match the circular cross-sectional shape of the suture ring and / or the prosthetic valve, the prosthetic valve will not fit optimally within the living annulus. As a result, the hemodynamics of the natural blood passing through and around the valve is inhibited, resulting in the formation of thrombi, possible emboli, and ultimately calcification of the valve structure.
To address this problem, flexible suture rings have been proposed for use with multi-part prosthetic valves. The suture ring will be implanted into the annulus of the living body using, for example, the procedure described above, i.e., lowering the suture array with a parachute. The suture ring will at least partially conform to the anatomy of the biological annulus. As an alternative, instead of using sutures, it has been proposed to drive staples through the suture ring and into the surrounding tissue to secure the suture ring.
However, if a mechanical valve or prosthetic valve is subsequently attached to the suture ring, the valve and the suture ring cannot mate effectively. For example, if the shape of the suture ring is distorted and conforms to the annulus, it will inhibit natural blood hemodynamics, cause leaks, and / or inhibit the performance of the prosthetic valve.
In addition, minimally invasive or minimally invasive procedures are often desirable because they reduce stress on the patient's body and / or promote post-operative recovery. Such procedures also include creating smaller access sites and / or accessing the procedure sites using ports. In order to introduce a prosthetic valve and / or suture ring into a patient's heart during valve replacement, the heart must be accessed, for example, by sternotomy or thoracotomy. The resulting opening must be large enough to allow passage of the prosthetic valve and also allow the physician to access and / or observe the implantation site. Thus, conventional procedures for implanting prosthetic heart valves may not be compatible with minimally invasive or minimally invasive procedures.
The present invention is directed to a prosthetic heart valve that is implanted into a patient's body. In particular, the present invention is directed to multi-part heart valve assemblies that are assembled together and devices and methods that guide and / or facilitate assembly and / or implantation of parts of a multi-part heart valve assembly. The present invention is also directed to an apparatus and method for assembling parts of a heart valve assembly including guides and / or other parts.
According to certain embodiments, an assembly is provided to replace a natural or prosthetic heart valve within a biological annulus. The assembly is an annular prosthesis that includes an annular member that is implantable within the biological annulus and is removably attached to the annular member to guide the valve member toward the biological annulus. One or more guide members and one or more connectors for securing the valve member to the annular prosthesis. In certain embodiments, the guide member may be attached to the annular prosthesis by one or more sutures, and the guide member may be removed from the annular prosthesis by cutting the one or more sutures. For example, cutting a single suture may allow one or more sutures to be released, or may allow the guide member to be released from the annular prosthesis. Instead, a plurality of sutures are provided, except that the plurality of sutures are in a desired position, eg, near the upper end of the guide member, so that the guide member can be released from the annular prosthesis by cutting the desired position once. May be collected or combined. Optionally, the suture may remain at least partially attached to the guide member such that the suture is removed from the annular prosthesis and / or patient along with the guide member.
Optionally, the assembly may include one or more suture cuffs extending outward from the annular member and / or one or more collars extending upward from the annular member to receive the valve member. Additionally or alternatively, the assembly may include a plurality of elongated guide rails or other leaders extending from the annular prosthesis, and the valve member will be guided along it. In this alternative, the guide rail is releasably connected to the guide member, e.g. through an opening at the top end of the guide member, biasing the guide rail away from the central axis of the assembly. Visualization may be improved during, for example, implantation, installation, and / or other surgical procedures.
According to another embodiment, a heart valve assembly is provided for implantation within a biological annulus. The assembly includes a first annular prosthesis that includes an annular member that is implantable within a biological annulus and a second valve prosthesis that is connectable to the first prosthesis. One or more guide members are removably attached to the first prosthesis to guide the second prosthesis toward the first prosthesis during implantation. For example, the one or more guide members include a plurality of guide shields spaced around the first prosthesis, thereby providing a passage through which the second prosthesis is directed toward the first prosthesis. It may be at least partially defined.
Optionally, the first prosthesis includes one or more suture cuffs extending outwardly from the annular member, a plurality of elongate leaders extending from the annular prosthesis and leading the valve member along and / or extending upwardly from the annular member. And a collar for receiving the valve member. The second prosthesis may include an annular frame and at least one valve element, such as a plurality of tissue leaflets. The first prosthesis and / or the second prosthesis may include one or more connectors for securing the second prosthesis relative to the first prosthesis.
According to yet another embodiment, a system for implanting a prosthetic valve within a biological annulus is provided. The system includes a first annular prosthesis including an annular member implantable within a biological annulus and one or more guide members or other leaders removably attached to the annular prosthesis, and a first prosthesis. And a delivery tool for carrying. The delivery tool includes an elongate shaft including a proximal end with a handle, a distal end dimensioned for introduction into a biological annulus, and an actuator for releasably carrying a first prosthesis. And. Optionally, the tool includes one or more elements to hold the one or more guide members away from the central axis of the first prosthesis to introduce the prosthetic valve toward the first prosthesis. It may be easy. Optionally, the system may include a second valve prosthesis that is guided toward the first prosthesis by one or more guide members. In this option, the second prosthesis may be carried by a tool that carries the first prosthesis or by a separate tool.
According to yet another embodiment, a method is provided for implanting a heart valve assembly within a biological annulus. The method includes implanting a first prosthesis into a biological annulus. The first prosthesis includes one or more guide members extending upward therefrom. The second valve prosthesis is advanced toward the first prosthesis. The second prosthesis is guided toward the first prosthesis by one or more guide members. Thereafter, the one or more guide members are removed from the first prosthesis, for example, before or after securing the second prosthesis to the first prosthesis. In an exemplary embodiment, the guide member may be sufficiently long to extend out of the biological annulus and / or the patient's body, and the guide member causes the second prosthesis to become the biological annulus. It may be easy to introduce. For example, the guide member may allow the second prosthesis to slide along the inner surface of one or more guide members and pass through intervening tissue and / or the guide member may be smooth A smooth and / or slippery surface may be provided so that the second prosthesis slides along the surface during placement of the second prosthesis at the desired anatomical site. Without the guide member, the friction between the surface of the second prosthesis and the interstitial tissue is too great and requires a higher force than desired for insertion of the second prosthesis and / or the friction is Reaching the desired final anatomical location within the biological annulus will cause the intervening tissue to buckle, collapse, and impinge the second prosthesis.
Other aspects and features of the present invention will become apparent from the following discussion, taken in conjunction with the accompanying drawings.
<Detailed description of exemplary embodiments>
Referring to the drawings, FIGS. 1 and 2 illustrate an embodiment of a heart valve assembly 110 that typically includes a gasket member 112 and a valve member 114. The gasket member 112 is an annular shaped body and typically defines a surface 116 and a central longitudinal axis 117 extending substantially perpendicularly from the surface 116. As shown, the gasket member 112 includes an annulus ring 118, a suture cuff 120, and a plurality of elongated guide rails, leaders or other elements 150 extending from the suture cuff 120 or other portions of the gasket member 112. And a plurality of guide shields 156 removably attached to the gasket member 112. As described further below, a fabric covering 121 is provided on one or more parts of the gasket member 112, such as on the annulus ring 118 and / or on the core of the suture cuff 120. May be provided
In some embodiments, the annulus ring 118 may be substantially circular. Alternatively, the annulus ring 118 may have a plurality of lobular shapes around it, such as a scallops or cusp (not shown). 3), which may be separated by 3). The annulus ring 118 may be formed of an elastic or superelastic material, for example, a metal such as nitinol or stainless steel, a polymer, or a composite material. As described further below, such materials will facilitate compression and / or expansion of the annulus ring 118.
In an exemplary embodiment, the annulus ring 118 may be cut from a flat sheet of substrate having a thickness desired for the annulus ring 118, such as by laser cutting, mechanical cutting, or the like. Good. Thus, the annulus ring 118 is initially formed as a long strip of material having a width corresponding to the desired width of the annulus ring 118 and a length corresponding to the desired circumference of the annulus ring 118. May be. The strip is wrapped around a mandrel or bound to a generally cylindrical shape with the ends adjacent to each other, and the strip is heat treated or programmed into a material with a generally cylindrical body. Thus, the process of creating the annulus ring 118 may be performed. The generally cylindrical body may include partially overlapping ends, separate ends that provide a “C” shape that is spaced apart and open, or ends that are bonded together. In other exemplary embodiments, the annulus ring 18 is formed from a solid rod of material such as, for example, nitinol, stainless steel, polymer, or composite material, such as machining, electrical discharge machining (“EDM”), laser cutting or It may be manufactured by other processes.
Optionally, for example when the material is in the austenitic state, the annulus ring 118 may be heat treated or programmed with shape memory in the strip material. For example, the programmed shape may be in an expanded or relaxed state, for example having a substantially circular shape. The composition of the material may be such that the annulus ring 118 substantially transitions to the martensite state at body temperature or lower, for example, at room temperature or lower (for example, 20 ° C. or lower). Accordingly, as described below, the annulus ring 118 is in a martensitic state (before delivery), such as to facilitate delivery of the annulus ring 118, eg, plastically compressed or deformed to a collapsed state. ) May be relatively flexible. When the body temperature is approached or about the body temperature (for example, 37 ° C. or more), the annulus ring 118 is transferred to substantially return to the austenite state. Thus, once the annulus ring 118 is exposed in the patient's body, the annulus ring 118 may be automatically biased toward an expanded state by austenite shape memory.
Alternatively, the material may be programmed to be in the austenitic state at both ambient and body temperature, but within the elastic and superelastic range of the material. In this manner, the annulus ring 118 is elastically compressed into a contracted state, however, when released from the restraint that maintains the annulus ring 118 in a contracted state, it expands in the direction of expansion. Will expand to elasticity.
For example, for ingrowth of tissue, the annulus ring 118 is at least partially woven by wrapping the fabric around the annulus ring 118 while accommodating the expansion and contraction of the annulus ring 118. It may be covered with. Optionally, a suture or the like (not shown) may be used to secure the fabric to the annulus ring 118 at a position excluding the end, for example, an intermediate position around the annulus ring 118. Alternatively, the entire annulus ring 118 may be freely slidable in the fabric wrapped around the annulus ring 118. Optionally, the gasket member 112 may include a flexible skirt and / or baleen elements (not shown), eg, surrounding the annulus ring 118 and / or inside the fabric cover. It may include an outward bias on a portion of the fabric cover on the outside.
With continued reference to FIG. 1, the suture cuff 120 may be attached to or extend around the annulus ring 118. The stitching cuff 120 may simply be one or more layers of fabric or other material that covers at least a portion of the annulus ring 118. For example, a fabric layer (not shown) may cover the entire annulus ring 118 (other than the connector and / or bearing surface, if any) and / or radially from the annulus ring 118. A portion of the material extending outward may be included.
Optionally, the sewing cuff 120 may include a flexible core material (not shown) and may be attached to or extend around the annulus ring 118. For example, the core may be secured around the annulus ring 118 by interference fit, bonding, fusing part of the core, or the like. Similar to the annulus ring 118, the core may be substantially covered with a fabric.
In an exemplary embodiment, the core may include a lattice (not shown) extending around the core, eg, at least two circumferential elements spaced apart, It may include a plurality of ribs or transverse elements extending from between the circumferential elements, thereby defining openings through the grid. The opening may be completely open, i.e. without any material. Alternatively, the opening may be a relatively thin wall of core material, i.e. a recess that includes a wall that is substantially thinner than the circumferential elements and / or ribs. In other embodiments, the core includes a base or knitted web and a plurality of fins or ribs extending from the knitted fabric to provide a seal between the suture cuff 120 and the valve member 114. A flexible structure that facilitates may be provided.
Typical materials for the core include silicone or other elastomeric materials, foam materials, fabrics, felts, polymers, and the like. Additionally or alternatively, the core may include a swellable material, such as foam material or sponge material, and will expand when exposed to a fluid such as blood. The material may be molded or molded into the core using, for example, known molding, extrusion, cutting or other manufacturing means. For example, the core may be formed into its own annular shape by injection molding or molding.
Alternatively, the core may be molded or molded into a flat sheet and rolled into an annular shape. In this alternative, the ends of the sheets may be bonded together using, for example, sutures, adhesives, ultrasonic welding, and the like. Optionally, to provide a tapered shape, one or more wedges (not shown) are cut from the strip to provide the desired tapered annular shape. Also good. In another option, part of the core may be separated from other parts to prevent, for example, puckering. For example, if the core is formed from a rolled sheet (not shown), the end of the sheet (also not shown) may remain free and allow the end to move relatively.
In the relaxed state (no external force), the sewing cuff 120 may take an undulating annular shape or a substantially flat annular shape. As shown in FIG. 1, the sewing cuff 120 may also be tapered, for example, to have a larger diameter or circumference at the upper end than at the end adjacent to the annulus ring 118. The tapered shape of the sewing cuff 120 may be defined in the range of, for example, about 20 to 45 degrees (20 to 45 degrees) with respect to the longitudinal axis 117.
The material of the core is substantially flexible, for example manufactured in the desired annular shape, and may be easily deformed, for example, deflected, stretched or compressed. The core may be sufficiently flexible and "floppy", i.e., so that the core easily adapts to a particular tissue and / or implantation arrangement encountered during implantation. Thus, as described further below, the core fits the surrounding tissue when the suture cuff 120 is placed over or within a living annulus in the patient's heart and / or When the valve member 114 is secured to the gasket member 112, the core will deform, for example, to enhance the seal between the valve member 114 and the gasket member 112.
Optionally, the gasket member 112 may include one or more additional parts. For example, the gasket member 112 may include a collar or stand-off (not shown) that will extend upward from the suture cuff 120 to receive the valve member 114. Additional information on the material, structure, and / or parts of gasket member 112 can be found in Application No. 10 / 327,817, US Publication No. 2004/0122516, Application No. 10/765725, US Publication No. 2005/0165479, and Application No. 11/069081. US Publication No. 2006/0195184, Application No. 11/420720, US Publication No. 2007/0016285, and co-pending application No. 11/567735 filed on Dec. 6, 2006.
With continued reference to FIG. 2, the guide rail 150 may include an elongated strip, fiber, or filament that includes a first or distal end 151 bonded or secured to the gasket member 112; A second end or proximal end 152. Optionally, the guide rail 150 may include one or more depth markers or other elements (not shown) spaced along at least a portion of their length, eg, One or more intervals may be spaced immediately adjacent to one end 151 and / or at a predetermined interval from the gasket member 112. In addition or alternatively, to secure the valve member 114 to or adjacent to the gasket 112, the guide rail 150 may include one or more retention elements 154, such as locking beads, latches, and the like. (latches), catches, ratcheting elements, etc. may be included.
As shown in FIG. 2, the guide rail 150 may be a flat strip formed, for example, from plastic or other material, and as described in US application Ser. No. 11/567735, as shown in FIG. 150 may have a retaining element 154 formed therein or adhered thereto. Alternatively, the guide rail 150 may be formed using known methods from wire or suture materials, for example, plastics such as polyethylene, metals such as stainless steel, cat guts, or composite materials. Good. The guide rail 150 has sufficient column strength to maintain a substantially linear and / or upward orientation, but for example, laterally toward the central axis 117 of the gasket member 112. It will be flexible enough to allow movement in the direction or away from the central axis 117.
The retaining element 154 may be formed integrally with the guide rail 15, for example, at the same time as the guide rail 150 is formed, or by removing some of the guide rail material, and / or a predetermined position of the guide rail 150. It may be a separate element (formed of the same or different material as the guide rail 150) that is glued, fused or attached to. In an alternative embodiment, the retaining element 154 on the guide rail 150 is a knot (not shown) made on the guide rail 150 and / or a bead (also shown) formed in place on the guide rail 150. May be included. Although only one retaining element 154 is shown for each guide rail 150, a plurality of retaining elements 154 are spaced from each other along each guide rail 150, similar to the elements shown in US 2005/0165479. May be provided.
With continued reference to FIG. 2, in one embodiment, the retention element 154 may include a tapered or ramped proximal end 154a and a substantially blunted distal end 154b. . Tapered proximal end 154a may provide a transition that allows valve member 114 to pass distally past retention element 154. As described further below, the non-pointed distal end 154b may provide locks that prevent the valve member 114 from passing back proximally through the retaining element 154.
The distal end 151 of each guide rail 150 may be attached to the gasket member 112 using, for example, one or more sutures, adhesives, or the like. For example, each guide rail 150 may include one or more holes (not shown) through the distal end 151, which will receive one or more sutures. The suture will be driven through the hole and will pass through the fabric cover and / or a portion of the suture cuff 120 to secure the distal end 151 to the gasket member 112. Additionally or alternatively, the distal end is attached to the gasket member 112 by receiving the distal end 151 through a portion of the casket member 112, such as through a fabric cover or a sewing cuff 120, by using an adhesive. May be. Optionally, distal end 151 may be fused or embedded in the core of suture cuff 120.
The guide rails 150 may be spaced apart from each other around or around the gasket member 112. For example, the guide rail 150 may be provided on a portion of the gasket member 112, which may be at the valve member 114 and / or at the commissures (not shown) of living annulus in which the gasket member 112 is implanted. Adapted. For example, as shown in FIGS. 1 and 2, three guide rails 50 may be provided for an aortic valve prosthesis having three joints. However, if desired, one, two or more guide rails (not shown) may be provided on the gasket member 112.
With further reference to FIGS. 3, 4A and 4B, the guide shield 156 extends upward and / or outward from the suture cuff 120, for example therebetween, as shown in FIG. 1 and described further below. A passage 124 for guiding the valve member 114 downward toward the gasket member 112 may be defined at least in part. Guide shield 156 may be a relatively thin and / or transparent sheet, such as a plastic or other polymer film or material such as polyester, Mylar®, such as high density polyethylene or low density polyethylene, polystyrene. Etc. can be formed. The sheet may have a desired shape defining a relatively wide base 156a attached to the gasket member 112 and a relatively narrow and loose upper end 156b, such as “mandolin”. ”Or inverted“ Y ”shape. Alternatively, the guide shield may have, for example, a generally triangular shape (not shown) that optionally includes a central open portion, thereby extending a pair of inverses extending from the upper end 156b to the base 156a. A “V” -shaped strip (not shown) may be defined.
The guide shield 156 is stiff enough to maintain its shape and / or orientation, but flexible enough to be deflected, folded or bent, if desired, for example, the guide shield 156 Would facilitate access to the surroundings. The transparency of the film may be such that the guide shield 156 does not interfere with the location of the gasket member 112 relative to, for example, the biological annulus or in the biological annulus, relative to the anatomy. Very useful for viewing through the guide shield 156 without moving the.
Optionally, upper end 156b may include one or more openings 158 for receiving guide rails 150 therethrough. As described further below, if the guide rail 150 is received in the opening 158, the opening 158 partially constrains the guide rail 150 away from the passage 124 or out of the operator's view during surgery. May be. Optionally, the upper end 156b of the guide shield 156 is a split including, for example, a slot 158a extending to the opening 158, and the guide rail is inserted into and / or removed from the opening 158. It may be easy to do. Alternatively, as shown in FIG. 4D, the upper end 156b ′ of the guide shield 156 ′ may include a slot 158a ′ that extends to or enters the opening 158 ′ from the side or from the bottom and It extends to the side edge of the portion 156b ′. Such a slot 158a 'provides lateral access to the opening 158' and still provides an opening 158 'that securely captures the guide rail 150 (not shown in FIG. 4D).
Additionally or alternatively, guide shield 156 and / or guide rail 150 include one or more other detents, connectors, etc. to releasably restrain guide rail 150 relative to guide shield 156. You may go out. For example, as shown in FIG. 3, in order to releasably restrain the guide rail adjacent to the guide shield 156, the upper end 156 b of the guide shield 156 has an arrangement of seatbelts or “zip ties” ( arrangement) 159 may be included. The array 159 may include an elongate belt or tab 159a that extends laterally from the upper end 156b of the guide shield 156 and a slot or other receptacle 159b that opposes the tab 159a. Optionally, tab 159a may include one or more connectors 159c, such as a ratchet, detent, or other retaining element, which secures tab 159a at one or more locations within receptacle 159b. Let's go. Additionally or alternatively, when the tab 159a is securely received in the receptacle 159b during implantation to provide better access and / or visualization to the gasket member 112, the array 159 may, for example, guide the guide shield 156 along the longitudinal axis 117. The guide shield 156 may be easily given a desired shape by restraining it with a curved shape around the guide shield 156.
With continued reference to FIGS. 3, 4A and 4B, each guide shield 156 may include a plurality of holes to facilitate releasably attaching the guide shield 156 to the gasket member 112. For example, as best seen in FIG. 3, a plurality of holes 155a are disposed along the base portion 156a of each guide shield 156 to receive sutures or other fastening elements. Alternatively, as best seen in FIG. 4A, sutures or the like may be driven into the fabric cover 121, the sewing cuff 120, and / or other portions of the gasket member 112. Further, the guide shield 156 includes a plurality of holes 155b, 155c that extend and / or spaced generally along the axis of the guide shield 156, e.g., an array of vertical holes 155b along the base 156a; And a series of holes 155c along the upper end 156b.
In addition, the array of vertical holes 155b along the base of 156a provides preferential flexibility along the axis defined by the holes 155b, eg during the folding process. For example, it may function as a hinge or provide a preferred bending edge for shaping the shield 156. For example, before attaching the guide shield 156 to the gasket member 112, the guide shield 156 is bent vertically, for example, along the axis of the hole 155b to form the guide shield 156 in a shape similar to the joint of the suture cuff 120. Also good. As described elsewhere herein, when the sket member 112 is placed on a gasket delivery tool, the bends may cause the guide shield 156 to deform while bending, or more. It will reduce the force required to provide a compact folded shape. In addition, bending, for example, when the gasket member 112 is released or positioned in a living annulus or other implantation site, biases the guide shield 156 toward the desired shape. Also good.
4A and 4B, an exemplary method for attaching the guide shield 156 to the gasket member 112 is shown. A suture 157 including a first end 157a and a second end 157b may be fed through the hole 155 to removably secure the guide shield 156 to the gasket member 112. For example, the first end 157a passes through one or more holes 155c in the upper end 156b, passes through one or more holes in the intermediate array of holes 155b, and one end of the base 156a. It may be sent into the hole 155a of the part. The suture 157a may then be directed through the hole 155a along the base portion 156a and through the fabric cover 121 of the gasket member 112, eg, from one end of the base portion 156a to the opposite end. Good. Thereafter, the suture 157 is fed back through one or more arrays of holes 155b and a series of holes 155c, and then the first end 157a is, for example, by a knot 157c, the second end. Will be tied or fixed to 157b.
Optionally, as shown in FIG. 4C, the stitching cuff 120 of the gasket member 112 may include one or more anchoring loops 123 sewn or secured to the stitching cuff 120, fabric cover 121, or gasket member 112, for example. May be included. For example, when releasing the guide shield 156 from the gasket member 112, the loop 123 will facilitate passage of the suture therethrough. As shown, the loop 123 is shown in a position corresponding to the opposite end of the base 156a or the hole 155a adjacent to the wings.
An exemplary method of attaching the guide shield 156 to the gasket member 112 includes first providing a series of, for example, three guide shields 156 made using the procedures and / or materials described elsewhere herein. You may go out. Prior to suturing the guide shield 156 to the gasket member 112, the guide shield 156 may be cleaned and / or sterilized, for example, by sonication and / or rinsing with pure water. The guide shield 156 may be bent vertically, for example, along the vertical hole 155b, and / or the upper end 156b may be bent outward. Thereafter, the guide shield 156 is placed on the gasket member, for example, by first placing an anchor loop of suture on the surface of the gasket member 112 using, for example, a pair of needles at both ends of the long suture, for example, in the center of the base portion 156a. 112 may be sutured. Thereafter, the suture may be sewn outside, for example through the anchor loop 123 to both ends of the base portion 156a and then to the upper hole 155c, where the ends of the suture are tied as shown in FIG. 4C. May be.
In this configuration, the guide shield 156 will be removed from the gasket member 12 simply by cutting or cutting the suture 157. Optionally, chain stitches or other stitches may be used, for example, it may be loosened by cutting in one place to remove the suture and consequently guide shield 156 after implantation. Would make it easier. Optionally, one of the ends 157a, 157b of the suture 157 is looped and / or secured through the hole 155c in the upper end 156b so that the suture 157 completely separates from the shield guard 156, for example. It may be prevented. For example, one of the sutures 157 may be cut below the position where one end (both ends) 157a, 157 is secured, and the suture is pulled from the other, for example, through various holes 155. The cutting side may be moved through. In this way, the suture 157 is completely separated from the gasket member 112, thereby allowing the guide shield 156 to be removed from the gasket member 112. In this way, the suture 157 is removed along with the guide shield 156, thereby avoiding the risk of leaving the suture 157 or a portion thereof. Further, this configuration allows the suture 157 to be cut and does not require that a cutting tool (not shown) be introduced all the way to the base 156a of the guide shield 156, but rather the guide shield. It may be possible to remove the guide shield 156 simply by introducing a cutting tool into the upper end 156b of 156.
Additionally or alternatively, the suture 157 is formed from a slippery material, such as stretched polytetrafluoroethylene (ePTFE) Gore-Tex®, polyester, ultra high molecular weight polyethylene (UHMWPE), polyethylene, and the like. Well, it will easily slide out of the various holes 155 when pulled from one end. Alternatively, if additional fixation is required, the suture 157 may be tied or fixed at one or more locations along or between the various holes 155, This may require cutting or severing suture 157 at multiple locations before removing guide shield 156 from gasket member 112. In this alternative, one or more sutures 157 would be secured through the hole 155a in the base portion 156a and the fabric cover 121 (or other member of the gasket member 112). For example, individual sutures (not shown) could be introduced through each of the holes and portions of the gasket member 112. In yet another alternative, the hole 155 may be eliminated and the suture 157 is directed through the desired location of the guide shield 156, for example using a sharp needle or other instrument carrying the suture 157. You can just be done.
Referring back to FIG. 1, the valve member 114 generally includes an annulus or frame 132 and one or more leaflets or other valve elements 133. Similar to the gasket member 112, the valve member 114 may include a fabric cover 135, such as the frame 132 and / or other parts of the valve member 114 that cover other than the valve leaflets 133. The frame 132 may be non-circular, for example, having a plurality of leaflet shapes corresponding to the shape of the annulus of the living body into which the valve member 114 is implanted. For example, the valve member 114 may include three tri-lobular shapes including three lobes separated by cusps or scallops, for example corresponding to the sinus of Valsalva above the aortic valve site. ). In certain embodiments, the valve member 114 may be a bioprosthetic valve member, eg, an annular frame 132 that supports a plurality of tissue leaflets 133. The frame 132 may include a plurality of struts (not shown for clarity) that will be attached to and / or support the leaflets 133. Similar to the valves disclosed in US Pat. No. 6,371983, Application No. 11 / 144,254, US Publication No. 2006/0276888, for example, the struts comprise a laminate structure comprising two or more sheets of flexible material. May be included.
Alternatively, the valve member 114 may be a connecting device, such as a connection adapter element as shown in application number 10/64639, US Publication No. 2005/0043760, against which a valve (not shown) ) May be connected or may receive a valve component. In another alternative, the valve 114 may include a mechanical valve or another valve (not shown), such as the valves disclosed in US 2005/0165479 and US 2007/0016285.
Optionally, valve member 114 may include one or more introducers or receivers (not shown) through which guide rail 150 will be received. For example, the receiver may include a receptacle attached to the fabric cover 135 at a desired location of the valve member 114, such as a joint or other desired location around the frame 132. The receptacle may include one or more connectors (not shown) and interacts with a connector on the guide rail 150, such as a retaining element 154. Alternatively, the valve member 114 may simply include a slot through the fabric cover 135 and / or the frame 132, for example, through which the guide rail 150 will be slidably received. In this alternative, the valve member 114 and / or the gasket member 112 may include one or more connectors (not shown) for securing the valve member 114 to or adjacent to the gasket member 112. For example, the gasket member 112 may include a collar (not shown) extending upwardly from the suture cuff 120 and / or the annulus ring 118 and the valve member 114 may be received in the collar. Additional information regarding the apparatus and method for securing the valve member 114 to the gasket member 112 can be found in the literature listed above, or application number 11/279246, US Publication No. 2006/0235508, or January 29, 2007. Application No. 11/66859 can be found.
With reference to FIGS. 5A-5C, an exemplary embodiment of a gasket delivery tool 160 is shown, including a shaft 162 including a proximal end 161, a distal end 163, and an actuator on the proximal end 161. 165. With further reference to FIGS. 6A and 6B, the delivery tool 160 may include a plurality of supports 166 spaced at the distal end, eg, around the longitudinal axis 167 of the tool 160. Good. In order to receive the gasket member 112 (such as any described herein) around the support 166, the support 166 is substantially rigid cylindrical hubs. Also good. The support 166 may generally define a diameter that is smaller than the gasket member 112, for example, smaller than the radius of the annulus ring 118.
Further, the tool 160 may include a plurality of arms 168 movably mounted at the distal end 163. For example, one end of the arm 168 may be fixedly attached to the distal end 163 of the tool 160, eg, proximal to the support 166, and the other end is positioned adjacent to the support 166. ) May be included. As shown, the arms 168 may be radially offset with respect to the supports 166 such that each arm 168 is disposed between adjacent supports 166. The arm 168 may be movable from an outer position (not shown) that defines a larger radius than the gasket member 112 to an inner position (shown in FIGS. 6A and 6B), where the tip is supported. Located between the bodies 166 or in the support 166.
Actuator 165 may include a lever or other mechanism that selectively moves the tip of arm 168 between an outer position and an inner position. In use, with the arm 168 in the outer position, the gasket member 112 is positioned between the support 166 and the arm 168, eg, the nadir regions of the suture cuff 120 radially aligned with the arm 168. May be arranged together. Thereafter, arm 168 is directed to an inner position, thereby securing gasket member 112 between support 166 and arm 168. As shown in FIGS. 6A and 6B, the gasket member 112 is deformed from a substantially circular expanded state to a contracted state of a “shamrock” shape defined by a plurality of leaf-like portions, for example, leaf-like portions. May be. The gasket member 112 may be elastically deformed or plastically deformed in a contracted state, and may be in a martensite state, for example, as in the previous embodiment.
Referring to FIGS. 7A-7C, during use, a heart valve assembly 110 included in any of the embodiments described herein may be placed in a patient's body, such as in or in a biological annulus 90. It may be transplanted adjacently. The biological annulus 90 may be a tricuspid valve, a mitral valve, an aortic valve, a pulmonary valve, or the like in a patient's heart (not shown). It may be a site for replacing an existing natural valve or a previously implanted heart valve.
Prior to implanting the heart valve assembly 110, the patient may be prepared for the procedure using known methods. For example, the patient may be placed on a cardiopulmonary bypass (CPB) and the patient's heart may be exposed, for example, by a sternotomy, thoracotomy, or other open or minimally invasive procedure. In order to access the annulus 90, an incision is made in the blood vessel above the valve to be replaced (not shown), for example, in the aortic valve replacement. Thereafter, existing natural or artificial valves and / or leaflets (also not shown) will be removed from the annulus 90 using known methods.
The heart valve assembly 110 including the gasket member 112 and the valve member 114 may have an anatomical encounter such as having a plurality of leaflets, aligning with the leaflets of the biological annulus 90, and It may be selected based on having a cross-sectional dimension corresponding to the internal cross-section of the biological annulus 90. Optionally, the gasket member 112 and / or valve member 114 may be selected to have a size larger than the biological annulus 90. For example, the gasket member 112 has a slightly larger diameter than the biological annulus 90 in a relaxed state, such that the gasket member 12 at least partially enlarges the biological annulus 90 during implantation. May be. Additionally or alternatively, for example, for supra-annular or intra-sinus implantation, the valve member 114 has a diameter or other cross-section that is substantially larger than the biological annulus 90. It may be adapted to larger sizes.
As shown in FIGS. 6A and 6B, the gasket member 112 may be placed on the tool 160 in a contracted state, for example, as described above. The gasket member 112 may be placed on the tool 160 immediately prior to introduction or may be prepared in advance as desired.
Referring to FIG. 7A, the gasket member 112 and the distal end 163 of the tool 160 may then be directed toward the biological annulus 90 in the direction of arrow 94. If necessary, the tool 160 may rotate about its longitudinal axis so that the leaf-like portion of the gasket member 112 is aligned with the joint (not shown) of the biological annulus 90. As shown in FIG. 7B, the gasket member 112 may be positioned such that the annulus ring 118 is received within the annulus, eg, the natural leaflets (or prosthesis) present therefrom are removed, From there, the suture cuff 120 is placed supra-annularly, for example, in the Valsalva sinus.
The arm 168 may then be directed to an outer position using, for example, the actuator 16 of the tool 160, thereby releasing the gasket member 112 within the biological annulus, as shown in FIG. 7B. Also good. As shown, the gasket member 112 may be elastically expanded toward its initial expanded state, e.g., expanding the annulus 90 of the body or directing the surrounding tissue 98 outward. Good. The tool 160 may be removed leaving the gasket member 112 in place within the biological annulus 90. As shown, the sewing cuff 120 is located in a supra-annular position relative to the natural annulus, although the annulus ring of the gasket member 112 may be located within the natural annulus. In an alternative embodiment, an expansion tool (not shown) is advanced into the gasket member 112 and to force (eg, plastically) expand the annulus ring 118 within the biological annulus 90. It may be enlarged.
Further, as shown in FIG. 7B, the guide shield 156 and the guide rail 150 may extend upward and / or outward from the gasket member 112. The guide shield 156 may be sufficiently long so that the upper end of the guide shield 156 is disposed outside the patient's body and / or outside the living annulus. For example, the guide shield 156 may enlarge a cut or other relatively narrow passage above the biological annulus 90. The guide shield 156 may at least partially define a passage 124 that communicates through the biological annulus 90 and the inner surface of the guide shield 156 provides a smooth and / or slippery surface to provide a valve member. 114 is facilitated to advance into tissue annulus 90 toward gasket member 112.
After releasing the gasket member 112 within the biological annulus 90, the gasket member 112 may be secured to the surrounding tissue 98. For example, a plurality of fasteners 96 may be delivered through the suture cuff 120 and into the surrounding tissue 98 using a tool (not shown). If desired, forceps, tweezers, or other tools may be used to manipulate the parts of the gasket member 112 while delivering the fastener 96. For example, a tool (not shown) may be used to hold the sewing cuff 120 and / or move the guide rail 150 and / or guide shield 156 to an unobstructed location. Due to the orientation, configuration and / or transparency of the guide shield 156, the guide shield 156 will not obscure observations and / or access within the biological annulus for delivering the fastener 96. Typical fasteners and methods for using them to secure the gasket member 112 include application number 10 / 327,821, US publication 2004/0122516, application number 10/64639, US publication 2005/0043760, application number. 10/681700, US Publication No. 2005/0080454, Application No. 11/004445, and US Publication No. 2006/0122634.
Still referring to FIG. 7B, the desired valve member 114 may be preloaded on a valve holder tool (not shown) by the manufacturer or user, or (if multiple sizes are available). A valve of the desired size may be selected and placed on the valve holder using, for example, one or more sutures. For example, a valve meter (or a growing series of valve meters) may be directed to the biological annulus 90 to determine an appropriately sized prosthetic valve to be delivered to the biological annulus 90. .
As can be seen in FIG. 7B, the guide rail 150 and guide shield 156 may extend outside the biological annulus 90 and / or may extend from the gasket member 112. Each guide rail 150 may rest on the valve member 114 through the receiver 130 until the guide rail 150 comes out of the upper end of the receiver 130, as described elsewhere herein. Optionally, the guide rail 150 may be inserted into a receptacle (not shown) in the valve holder before or after being placed on the valve member 114 through the receiver 130.
Thereafter, the valve holder supporting the valve member 114 may be directed, for example, beyond the guide rail 150 and into the biological annulus 90. When the guide rail 150 is coupled to the guide shield 156 and / or constrained by the guide shield 156, the guide rail is released from the guide shield 156 and the valve member 114 moves the guide rail 150 toward the gasket member 112. It will allow you to slide down freely. During introduction, the valve member 114 may slidably contact the inner surface of the guide shield 156 extending from the gasket member 112. In this manner, the guide shield 156 may provide a substantially smooth and / or slippery surface that passes the valve member 114 through a narrow and / or partially obstructed passageway. It may be easy to advance into the biological annulus 90. Optionally, at least the inner surface of guide shield 156 may be covered with a slippery coating or the like to minimize friction between guide shield 156 and valve member 114.
Optionally, guide rail 150 may include one or more markers 151 at a predetermined location, eg, a known distance from gasket member 112. The marker 151 may provide a user confirmation of the position of the valve member 114 relative to the gasket member 112 and / or by indicating, for example, that the valve member 114 has passed over the retaining element 154 on the guide rail 150. When the valve member 114 is secured to the gasket member 112, when the valve member 114 is received by a collar (not shown) on the gasket member 112, and / or when the valve member 114 is connected to the gasket member 112. Visual confirmation may be provided. As described elsewhere herein, the valve member 114 may be advanced to engage the connector of the valve member 114 with the retaining element 154 or the like of the gasket member 112. To facilitate this, during advancement of the valve holder and / or valve member 114, for example, a “click” or audible and / or tactile response is provided to engage the cooperating connector. The user will pull the guide rail 150 or apply proximal tension until he is sure. Each set of connectors may be engaged in sequence or simultaneously.
Optionally, the guide rail 150 may include a weakened region above the holding element 154, for example, and may be severable above the holding element 154. Thereafter, the guide rail 150 may be disconnected and separated from the gasket member 112, for example, above the retaining element 154, and the guide rail 150 may be removed from the patient's body. Alternatively, an actuator (also not shown) of the valve holder (not shown) may be pulled or manipulated proximally to break or sever the guide rail 150 at each weak area.
Referring to FIG. 7C, the guide shield 156 may be removed from the gasket member 112 before or after the guide rail 150 is cut. As described above with reference to FIGS. 4A and 4B, the suture 157 may be cut or severed to release the guide shield 156 and allow them to separate from the gasket member 112. May be. Once cut, the suture 157 may be easily unwound to allow the guide shield 156 and the suture 157 to be removed from the gasket member 112 simultaneously. Alternatively, guide shield 156 and suture 157 may be removed separately from gasket member 112 and from the patient's body. The valve member 114 may be released from the valve holder, for example, before or after cutting the guide rail 150 and / or removing the guide shield 156, thereby allowing the heart valve assembly implanted within the annulus 90 of the living body. 110 may be provided.
Referring to FIGS. 8A and 8B, another embodiment of the gasket member 212 is illustrated, which includes a set of guide shields 256 (only one is shown for simplicity). The gasket member 212 may be formed, for example, including an annulus ring 218, a sewing cuff 220, and a plurality of guide rails or other leaders 250, as in other embodiments described herein. Good. Each of the gasket shields 256 may be formed, for example, including a wide base portion 256a and an upper end portion 256b, similar to the other embodiments described herein, such as the guide rail 250. One or more features (not shown) may be included to releasably restrain each of the guide shields 256 to each other.
Unlike other embodiments, each gasket shield 256 may include one or more sutures or other filaments 257 secured to the base portion 256a, which passes through a portion of the gasket member 212, for example, sutures. It may be slidably received through the cuff 220 and / or the fabric cover. If desired, the suture 257 may optionally be received through a loop (not shown) formed in the suture cuff 220. When the gasket member 212 is introduced into a living annulus (not shown), the suture 257 may be long enough to extend completely out of the patient's body. The free ends of the sutures 257 may be knitted or connected together so that the sutures 257 are brought together.
Initially, as shown in FIG. 8A, guide shield 256 may be provided away from gasket member 212, but will be slidably received through gasket member 212 by suture 257. Thereafter, similar to other embodiments described elsewhere herein, the gasket member 212 will be introduced into a biological annulus and implanted or secured therein. The suture 257 may be long enough so that the guide shield 256 is placed outside the patient's body, for example, to be maintained outside the surgical field. Due to the guide shield 256 away from the gasket member 212, the gasket member 212 may be more easily manipulated and / or monitored during introduction and implantation. For example, one or more clips, sutures, or other fasteners (not shown) can be delivered through the suture cuff 220 into the surrounding tissue without having to manipulate the guide shield to an unobstructed location. Let's go.
Referring to FIG. 8B, once the gasket member 212 is secured within the biological annulus, the guide shield 256 may then be directed to the biological annulus, for example, by pulling the end of the suture 257. Good. This action causes the suture 257 to slide through the gasket member 212 and pulls the guide shield 256 into the annulus of the living body to oppose the suture cuff 220 as shown or adjacent to the gasket member 212. right. Thereafter, a valve (not shown) will be introduced into the biological annulus and secured to the gasket member 212, as in other embodiments described elsewhere herein. For example, if it is desired to remove the guide shield 256, such as after the valve is secured to the gasket member 212, the upper end portion 256b of the guide shield can be easily pulled so that the suture 257 is attached to the gasket. It may slide through member 212 to the outside.
Alternatively, the guide shield 256 may be provided adjacent to the gasket member 212, as shown in FIG. 8B, before the gasket member 212 is introduced into the living annulus. For example, the gasket member 212 may be supported by a delivery tool (not shown), for example, in a compressed state, which may constrain the guide shield 256 by the gasket member 212. This may facilitate the introduction of the gasket member 212 without handling the guide shields 256 that are loose or separated from the gasket member 212, which also places the sutures 257 out of the way to disturb them. It may be necessary to maintain.
If the gasket member 212 is introduced into the biological annulus, if desired, the guide shield 256 may be pulled from the biological annulus, ie, to the position shown in FIG. 8A, before delivering the fastener through the gasket member 212. May be. After delivering the fastener, the guide shield 256 may be pulled on the annulus of the living body as described above.
In another alternative, the guide shield 256 may remain adjacent to the gasket member 212 while the fastener is delivered, as in the previous embodiment. Similar to the previous embodiment, the guide shield 256 may be removed after the valve is introduced and / or secured to the gasket member 212.
Referring to FIGS. 9A and 9B, in another alternative embodiment, gasket member 312 and guide shield 356 (only one is shown for simplicity), as with other embodiments described elsewhere herein. May be provided). Unlike previous embodiments, the guide rail may be constrained in a rounded or other contracted configuration. For example, as shown, the tubular sleeve 340 may receive at least a portion of the periphery of the guide rail 356 after the guide rail 356 is rolled, bent, or reduced in width.
The sleeve 340 may be formed of a material similar to the guide shield 356, for example, may be substantially flexible and / or transparent, and may be longer or shorter than the guide shield 356. The sleeve 340 will minimize obstacles caused by the guide shield 356 during introduction, for example, maximizing access to the periphery of the gasket member 212, such as delivering a fastener therethrough. If desired, the sleeve 340 will simply slide axially around the guide shield 356, eg, by pulling the outer end of the sleeve 340 out of the biological annulus. The guide shield 356 may then be used to guide the introduction of the valve into the biological annulus toward the gasket member 312 and / or unfolding, unfolding or opening. Provides a surface for ease. Alternatively, the sleeve 340 may include one or more weak regions (not shown) that extend axially along the sleeve 340, for example, which is torn or separated around the guide shield 356. Will facilitate removal of the sleeve 340 from the
If the guide shield 356 is opened, the procedure may be completed using any of the methods described herein. As such, the guide shield 356 may be removed by cutting one or more sutures that secure the guide shield 356 to the gasket member 312. Alternatively, the guide shield 356 may be slidable from the gasket member 312, for example, as described above with reference to FIGS. 8A and 8B.
Elements or members shown in any embodiment herein are illustrative for a particular embodiment and may be used in combination with other embodiments disclosed herein. Will be recognized.
While the invention is susceptible to various modifications and alternative forms, specific embodiments thereof are shown in the drawings and are described in detail herein. However, the invention is not limited to the specific forms or methods disclosed, but on the contrary, the invention within the scope of the appended claims covers all modifications, equivalents, and alternatives. Should be understood.
FIG. 1 is a perspective view of a two-piece heart valve assembly including a gasket member having a plurality of guide shields extending from the gasket member and a valve member. FIG. 2 is a perspective view of a gasket member included in the assembly of FIG. 1 and includes an annular prosthesis and a plurality of guide shields and guide rails extending from the annular prosthesis. FIG. 3 is a front view of an exemplary embodiment of a guide shield, including a suture hole, a receiving slot for a guide rail, a belt and a buckle. FIG. 4A is a top view of the guide shield, which is attached to the gasket member with a suture. FIG. 4B is a side view of the guide shield, which is attached to the gasket member with a suture. FIG. 4C shows details of an alternative to the releasable guide shield securing method shown in FIGS. 4A and 4B, with the loop secured to the gasket member. FIG. 4D is a detail of an alternative embodiment of the upper end of the guide shield. FIG. 5A is a side view of a tool for delivering the gasket member of FIG. FIG. 5B is a perspective view of a tool for delivering the gasket member of FIG. 5C is an end view of a tool for delivering the gasket member of FIG. 6A is an end view of the distal end of the tool of FIGS. 5A-5C, with the gasket of FIG. 2 secured thereto in a folded or shrunken state (for clarity, guide shield and guide rail). Is omitted). 6B is a side view of the distal end of the tool of FIGS. 5A-5C, with the gasket of FIG. 2 secured thereto in a folded or collapsed state (for clarity, guide shield and guide rail). Is omitted). 7A is a cross-sectional view of a biological annulus and illustrates a method for implanting a heart valve assembly including the gasket of FIG. 7B is a cross-sectional view of a biological annulus and illustrates a method for implanting a heart valve assembly including the gasket of FIG. 7C is a cross-sectional view of a biological annulus and illustrates a method for implanting a heart valve assembly including the gasket of FIG. FIG. 8A is a perspective view of a gasket member that includes a guide shield that is slidable toward or away from the gasket member. FIG. 8B is a perspective view of the gasket member, including a guide shield that can slide toward or away from the gasket member. FIG. 9A is a perspective view of a gasket member including a guide shield constrained within a removable sleeve. FIG. 9B is a perspective view of the gasket member including a guide shield constrained within a removable sleeve.
A heart valve assembly implantable within a biological annulus,
A first prosthesis including an annular member implantable within the biological annulus and a suture cuff extending outwardly from the annular member;
A second valve prosthesis including an annular frame and at least one valve element;
One or more guide shields removably attached to and extending upwardly from the first prosthesis, the one or more guide shields passing through the first prosthesis through the first prosthesis; Said one or more guide shields defining at least partially a passage directed toward the prosthesis.
The first prosthesis includes a plurality of elongate leaders extending from either the annular member or the suture cuff;
The heart valve assembly according to claim 1, wherein the leader is receivable through the second prosthesis to guide the second prosthesis toward the first prosthesis.
The heart valve assembly of claim 2, wherein the second prosthesis includes a plurality of receptacles for slidably receiving each of the leaders therethrough.
4. The heart valve assembly according to claim 3, wherein the receptacle and the leader include cooperating connectors for securing the second prosthesis to the first prosthesis.
The cooperating connector is
One or more holding elements on the leader;
The receptacle includes one or more latches for engaging the holding element as the leader passes through the receptacle;
The heart valve assembly according to claim 4, thereby preventing subsequent movement of the second prosthesis away from the first prosthesis.
The heart valve assembly according to claim 2, wherein the one or more guide shields include a plurality of guide shields disposed adjacent to each of the plurality of leaders.
The guide shield includes an upper end;
The upper end includes an element for releasably holding the leader to the guide shield to maintain the leader away from the passage defined at least in part by the guide shield. The heart valve assembly according to claim 6.
Each of the guide shields is
A wide base portion extending partially around the first prosthesis;
The heart valve assembly of claim 1 including a narrow upper end.
The base portion is removably attached to the first prosthesis by one or more sutures, the suture to allow the base portion to be separated from the first prosthesis. 9. The heart valve assembly according to claim 8, wherein the heart valve assembly is cut.
Each of the guide shields is disposed away from the first prosthesis and is directable with respect to the first prosthesis to guide the second prosthesis toward the first prosthesis. The one or more guide shields are slidably attached to the first prosthesis by one or more tethers so as to at least partially define the passageway for the device. The heart valve assembly according to claim 1.
Each of the one or more guide shields is removable from the first prosthesis by pulling an upper end of the guide shield;
11. The heart valve assembly of claim 10, wherein the tether is free to slide through the first prosthesis.
A heart valve system for implanting a valve prosthesis in a living annulus,
An annular prosthesis comprising an annular member implantable within the biological annulus,
The annular member is radially inwardly compressible from a relaxed state to a contracted state and facilitates delivery into the annulus of the living body;
The annular member is elastically expandable toward the relaxed state, the annular prosthesis;
A plurality of guide shields removably attached around the annular prosthesis, wherein the guide shields define a passageway in which a second prosthesis is directed toward the first prosthesis. A heart valve system comprising: a guide shield.
A wide base portion partially extending around the first prosthesis;
13. The heart valve system of claim 12, including a narrow upper end.
The base portion is removably attached to the annular prosthesis by one or more sutures, and the suture is cut to allow the base portion to be separated from the annular prosthesis. The heart valve system according to claim 13, wherein:
The guide shield is disposed remotely from the annular prosthesis and is at least partially defining the passage for directing the valve prosthesis toward the annular prosthesis. The heart valve system according to claim 12, wherein the guide shield is slidably attached to the annular prosthesis by one or more tethers.
An elongated shaft including a proximal end;
A distal end dimensioned for introduction into the biological annulus;
An actuator for deforming the annular member from the relaxed state to the contracted state;
The heart valve system of claim 12, further comprising a delivery tool comprising:
The relaxed state includes a substantially circular shape,
The heart valve system according to claim 12, wherein the contracted state includes a plurality of lobular shapes.
The heart valve system of claim 12, further comprising a plurality of elongate leaders extending from the annular prosthesis for guiding a valve prosthesis toward the annular prosthesis.
Further includes a valve prosthesis,
The heart valve system of claim 18, wherein the leader is receivable through the valve prosthesis to guide the valve prosthesis toward the annular prosthesis.
20. The heart valve system of claim 19, wherein the valve prosthesis includes a plurality of receptacles for slidably receiving each of the leaders.
21. The heart valve system of claim 20, wherein the receptacle and the leader include cooperating connectors for securing the valve prosthesis to the annular prosthesis.
The upper end includes an element for releasably holding the leader to the guide shield to maintain the leader away from the passage defined at least in part by the guide shield. The heart valve system according to claim 18.
23. The heart valve system of claim 22, wherein the element includes a slot at the upper end of the guide shield.
A prosthesis for receiving a valve prosthesis for replacing a natural or prosthetic heart valve in a pre-existing biological annulus,
An annular member implantable within the annulus of the living body;
A suture cuff extending outward from the annular member;
And a plurality of guide shields extending upward and / or outward from one of the annular member and the sewing cuff.
The prosthesis according to claim 24, wherein the guide shield is detachably attached to one of the annular member and the sewing cuff.
26. The prosthesis of claim 25, wherein the guide shield is removably attached to the suture cuff by one or more sutures.
The one or more sutures pass through the holes in the guide shield and the suture cuff so that each guide shield is removable from the suture cuff once each of the one or more sutures is cut once. 27. The prosthesis according to claim 26, wherein the prosthesis is arranged.
The suture cuff includes one or more anchor loops for receiving the suture therethrough so that the suture can slide through the anchor loop when the suture is cut. The prosthesis according to claim 26, characterized in that:
One end attached to one of the annular member and the sewing cuff;
A free end that is receivable through the suture cuff to guide the valve prosthesis toward the suture cuff;
25. The prosthesis of claim 24, further comprising a plurality of elongate leaders comprising:
30. The prosthesis of claim 29, wherein the guide shield includes one or more elements for releasably holding the leader away from a central axis of the annular member.
25. The guide shield of claim 24, wherein the guide shield has an inner surface that at least partially defines a passage for guiding the valve prosthesis toward the suture cuff between the guide shields. Prosthesis.
JP2009508004A 2006-04-29 2007-04-29 Multi-membered prosthetic heart valve assembly, apparatus using the same, and method of using the same Active JP5016667B2 (en)
US60/746,038 2006-04-29
JP2009535127A JP2009535127A (en) 2009-10-01
JP5016667B2 true JP5016667B2 (en) 2012-09-05
JP2009508004A Active JP5016667B2 (en) 2006-04-29 2007-04-29 Multi-membered prosthetic heart valve assembly, apparatus using the same, and method of using the same
JP2011522604A (en) * 2008-06-05 2011-08-04 メドトロニック，インコーポレイテッド Connection system, fabrication method, and use for a two-piece prosthetic heart valve assembly
EP2012712B1 (en) 2016-02-10
JP5386664B2 (en) 2014-01-15 Biologically implantable prosthesis and method of use
JP4411082B2 (en) 2010-02-10 Annuloplasty system
2011-03-01 A711 Notification of change in applicant