An exemplary valve repair device for repairing a native valve of a patient includes a coaption element, a pair of paddles, and barb portions. The barb portions extend directly from at least one of the coaption element and the pair of paddles.

The present invention discloses a novel valve clamping device and a valve clamping system. The valve clamping device includes a first clamping component, a second clamping component, and a fixing component for fixing the first clamping component and the second clamping component. The first clamping component has at least two first clamping arms. The second clamping component has a corresponding number of second clamping arms. Each of the first clamping arms and the corresponding second clamping arm may be combined into a pair of clamps. The clamping device may adopt designs of a smooth transition at the top, the clamping teeth having high clamping stability, and the fixed ring achieving the purpose of “one thread for two uses”.

Medical delivery system for accessing a tricuspid valve via an inferior vena cava, including an outer guide catheter, an inner guide catheter and an interventional catheter. The first deflection portion of the outer guide catheter is steerable to define a first outer-guide-catheter curve and the second deflection portion of the outer guide catheter is steerable to define a second outer-guide-catheter curve and the first deflection portion of the inner guide catheter is steerable to define a first inner-guide-catheter curve.

The present disclosure provides a method for contracting heart tissue using a transcatheter annuloplasty system. The system includes a plurality of anchoring components, a flexible tightening string and a flexible delivery member. The tightening string is coupled with a first anchoring component and the delivery member. The method includes: implanting the first anchoring component into the heart tissue, the tightening string entering a body along with the first anchoring component, and a proximal end of the delivery member extending outside the body; delivering each of remaining anchoring components, along the delivery member, to the tightening string and implanting it into the heart tissue; and tightening the tightening string. Therefore, after the plurality of anchoring components are implanted at different positions, along a circumferential direction of the mitral annulus, the tightening string is tightened to adjust a spacing of the anchoring components so as to contract the heart tissue.

Coaptation assist device for repairing cardiac valves and associated systems and methods are disclosed herein. A coaptation assist device configured in accordance with embodiments of the present technology can include, for example, a fixation member configured to press against cardiac tissue proximate to a native valve annulus, and a stationary coaptation structure extending away from the fixation member. The coaptation structure can include an anterior surface configured to coapt with a first native leaflet during systole and a posterior surface configured to displace at least a portion of a second native leaflet. The device also includes at least one sensor configured to detect parameters associated with at least one of cardiac function and device functionality. The sensors can be pressure sensors configured to detect left atrial pressure and/or left ventricular pressure.

A prosthetic heart valve for replacement of a native heart valve having a native valve annulus includes a stent body having a proximal end adjacent an inflow end and a distal end adjacent an outflow end and including an annulus section, the stent body having a radially collapsed condition and a radially expanded condition, one or more prosthetic valve elements mounted to the stent body and operative to allow flow in an antegrade direction from the inflow end to the outflow end but to substantially block flow in a retrograde direction from the outflow end to the inflow end, a cuff coupled to the stent body, the cuff having a mobile portion that is moveable relative to the stent body, and at least one engagement element remote from the stent body.

The present invention relates to a prosthetic device for deployment in the native aortic valve region of a heart, comprising a tubular spacer element, the spacer element being configured for placement within the native aortic valve region of a heart without contacting to the native aortic annulus; the prosthetic device further comprises at least one anchoring element designed for anchoring the prosthetic device within the heart, and at least one connecting element, coupling the spacer element to the at least one anchoring element; in the prosthetic device, the tubular spacer element further comprises a coaptation skirt element being connected to the outer surface of the spacer element, such, that the coaptation skirt element is inflatable during diastole.

An implant comprises a wall that surrounds a lumen. A delivery tool comprises a catheter, a control assembly, and an ultrasound tool. The catheter is transluminally advanceable into a subject, and has a distal opening. The implant can be delivered via the catheter. The control assembly can advance at least a portion of the wall out of the distal opening, and can steer the catheter to place the portion against a site of a tissue of the subject, the site disposed distally from the portion and opposite the distal opening. The ultrasound tool can (i) position an ultrasound transceiver within the lumen and facing the portion, and (ii) facilitate imaging of the site by transmitting ultrasound energy through the portion. An anchor driver can anchor the implant to the tissue by driving an anchor through the portion and into the site. Other embodiments are also described.

A prosthetic spacer assembly includes a spacer body, a first anchor, and a second anchor. The first anchor and the second anchor are each connected to the spacer body. The first anchor is configured to capture a first native valve leaflet between the first anchor and the spacer body. The second anchor is configured to capture a second native valve leaflet between the second anchor and the spacer body.

A distal end of a guide catheter is transvascularly advanced into a left ventricle of a heart of a subject. While the distal end of the guide catheter remains disposed in the left ventricle, a first tissue anchor of an implant is deployed from the distal end of the guide catheter. Subsequently, the guide catheter is retracted while progressively exposing the implant. Subsequently, a second tissue anchor of the implant is anchored to a posterior annulus of a mitral valve of the heart by deploying at least part of the second anchor within a left atrium of the heart, such that the implant extends from the first tissue anchor, over an atrial side of a posterior leaflet of the mitral valve, and to the second tissue anchor. Other embodiments are also described.