Abstract: Medical devices and methods for closing an anatomical aperture in a tissue are disclosed. The medical devices can include distal and proximal support structures, which can include a plurality of anchor members. A connection element can connect the distal and proximal support structures, and be configured to twist to create a seal within the medical device. In certain embodiments, a sheath about the medical device can be retracted to expose the distal support structure, which can allow it to revert to an anchoring configuration from a delivery configuration, such that the anchor members can engage an interior surface of the tissue. After twisting the connection element to form a seal, the sheath can be further retracted to expose the proximal support structure, which can allow it to revert to an anchoring configuration from a delivery configuration, such that the anchor members can engage an exterior surface of the tissue.

Abstract: A prosthesis having first and second prosthetic sections is disclosed. The first prosthetic section includes a stent structure that may contain a first prosthetic valve secured therein and the second prosthetic section includes an annular frame that may contain a second prosthetic valve secured therein. When the prosthesis is in an expanded configuration, the annular frame extends from the stent structure such that the first and second prosthetic sections are laterally offset from each other. In a method in accordance herewith, the first and second prosthetic sections may include prosthetic aortic and mitral valves, respectively, and the heart valve prosthesis is configured to replace one or both of the native aortic and mitral valves of the heart in a single transcatheter heart valve implantation procedure.

Abstract: An integrated balloon dilation and valve prosthesis delivery device is provided having a capsule that is configured to surround a collapsed valve prosthesis and that contains a balloon on an exterior surface.

Abstract: Heart valve delivery systems and methods of delivering and implanting heart valves using delivery catheters are disclosed. The delivery systems can include a handle assembly with a rotatable control knob and a catheter including an introducer shaft, an intermediate shaft extending from the handle assembly, an inner shaft extending from the handle assembly, and a capsule for containing a prosthesis. The distal end of the capsule can be connected to a distal end of the inner shaft, which can be moved in a distal direction by the rotatable control knob to deploy the prosthesis. By advancing the introducer through the deployed prosthesis and retracting the capsule to mate with the introducer, a smooth profile can be created for retraction of the system through the deployed prosthesis, minimizing hang-ups and snagging.

Abstract: Prosthetic valve introducer systems and methods for deploying a heart valve prosthesis within a body lumen are disclosed. In certain embodiments, the valve introducer can include a delivery shaft to house a prosthetic valve and a distal tip, and a deployment element to push a prosthetic valve out of the distal tip of the delivery shaft. The valve introducer can include at least one finger gripping element. The delivery shaft can be inserted into a body lumen and advanced to a desired deployment location. In certain embodiments, the prosthetic valve can be deployed by pushing the deployment element in a distal direction, thereby pushing the prosthetic valve out of the distal tip of the delivery shaft.

Abstract: The implant implantation unit (2), at a determined position in the tubular element (51) with a wall comprising a cavity (50), is pushed there by a catheter (60) and the unit comprises deformable feelers (31) to, under the control of remote activation elements (42), change from a stowed form to a deployed functional form, to detect the cavity (50) and position itself there with reference to the position of the cavity.

Abstract: The implant implantation unit (2), at a determined position in the tubular element (51) with a wall comprising a cavity (50), is pushed there by a catheter (60) and the unit comprises deformable feelers (31) to, under the control of remote activation elements (42), change from a stowed form to a deployed functional form, to detect the cavity (50) and position itself there with reference to the position of the cavity.

Abstract: The implant implantation unit (2), at a determined position in the tubular element (51) with a wall comprising a cavity (50), is pushed there by a catheter (60) and the unit comprises deformable feelers (31) to, under the control of remote activation elements (42), change from a stowed form to a deployed functional form, to detect the cavity (50) and position itself there with reference to the position of the cavity.

Abstract: A crimping device used with a medical device can include at least one force-applying surface configured to compress the medical device by applying a force to a surface of the medical device. The crimping device also includes at least one protruding element extending from the force-applying surface and arranged to least partially extend into one of the openings defined by frame struts while the medical device is being crimped. The extension of the at least one protruding element at least partially into one of the openings prevents at least a portion of the soft layer of the medical device from protruding between struts of the outer frame of the medical device while the device is being crimped.

Abstract: Medical devices for closing a hole or holes in a subject's body, such as those related to transapical procedures, are disclosed. The medical devices can include a force-providing portion and a tissue-attachment portion. The medical devices can be configured for multiple positions including at least a constrained position and an unconstrained position. In some embodiments, the medical device may be used on a delivery device or delivery tool. In some embodiments, the force-providing portion can pivot radially outward and the tissue-attachment portion can become more constrained, and the hole can be at least partially closed. In some embodiments, the tissue-attachment portion can include a plurality of pins that assume a hook shape.

Abstract: Heart valve prosthesis recapture devices and methods for recapture are disclosed, which can be used for recapturing a partially deployed heart valve prosthesis. The recapture device comprises a recapture sleeve, configured to envelop and collapse a partially deployed heart valve prosthesis. The recapture sleeve comprises a distal end, configured to be securely attached to a guide wire, and a proximal end, comprising an opening along a longitudinal axis of the recapture sleeve. The opening can be configured to expand as it engages the heart valve prosthesis, and be biased toward a closed configuration. An attachment element can interface with the distal end of the recapture sleeve and be securely attached to a guide wire, such as by crimping. The recapture sleeve can include a support structure comprising at least one spine and a plurality of ribs.

Abstract: Valve introducer systems and methods for implanting heart valve prostheses are disclosed, where a valve introducer includes an adjustable deployment mechanism comprising a deployment element and an implantation depth controlling element having a distal end and an adjustable length. The valve introducer also includes a tubular member having a distal end, configured to deliver a heart valve prosthesis, and a length extending from a fixed reference point. The implantation depth controlling element can comprise an inner and an outer cylinder, such as where the outer cylinder has interior threads, and the inner cylinder has exterior threads. The adjustable deployment element can include a depth gauge, wherein the depth gauge indicates the length the tubular member extends beyond a fixed reference point. In certain embodiments, the adjustable deployment element can also be configured to be secured to a cannula.

Abstract: A dual valve prosthesis having first and second prosthetic valve sections is disclosed. The first prosthetic valve section includes a stent structure with a first prosthetic valve secured therein and the second prosthetic valve section includes an annular frame with a second prosthetic valve secured therein. When the dual valve prosthesis is in an expanded configuration, the annular frame extends from the stent structure such that the first and second prosthetic valves are laterally offset from each other. In a method in accordance herewith, the first and second prosthetic valve sections include prosthetic aortic and mitral valves, respectively, and the dual heart valve prosthesis is configured to replace both the native aortic and mitral valves of the heart in a single transcatheter heart valve implantation procedure.

Abstract: The present invention is directed to prostheses including a support structure having a proximal end and a distal end, and a motion limiting member attached to the distal end of the support structure, wherein the motion limiting member is configured to restrict radial expansion of the distal end of the support structure. Methods for delivering the prosthesis are also provided.

Abstract: A prosthesis retaining assembly for securing an implantable prosthesis to a catheter assembly can include a first member including a prosthesis retaining slot configured to retain a portion of the prosthesis. The retaining slot can have a first portion with a first width and a second portion with a second width. The first portion can be distal to the second portion. The second width can be larger than the first width, and the retaining slot can have an opening at a first surface of the first member. The prosthesis retaining assembly can also include a second member configured to be move relative to the first member. The second member can be configured to move to a position that obstructs a portion of the opening of the retaining slot.