An implant system for restoring and improving physiological intracardiac flow in a human heart is provided including a force transducting, structurally stabilizing, and functionally assisting ventricular inflatable cardiac implant within a human heart for restoring and improving physiologic intracardiac flow, restoring the ventricular vortex, preventing atrioventricular pressure gradient loss, mitigating valvular regurgitation, and utilizing native energy and force, via force transduction, to restore geometric elliptical proportion and function to the atria, the ventricles and ventricular walls, and the valvular apparatus itself.

Shunt devices and a method for continuously decompressing elevated intraocular pressure in eyes affected by glaucoma by diverting excess aqueous humor from the anterior chamber of the eye into Schlemm's canal where post-operative patency can be maintained with an indwelling shunt device which surgically connects the canal with the anterior chamber. The shunt devices provide uni- or bi-directional flow of aqueous humor into Schlemm's canal.

One aspect of the invention provides a flow-diverting system including: a first stent having a proximal end, a distal end and a first sidewall opening; and a second stent having a proximal end, a distal end and a second sidewall opening. The first sidewall opening is of sufficient size for the distal end of the second stent to pass from inside the first stent through the first sidewall opening. The second sidewall opening is of sufficient size for fluid flow from inside the second stent through the second sidewall opening into the first stent.

The present disclosure is related to medical devices, stents, drainage devices, and the like, which feature a doubled back design. Various embodiments described herein have a portion with overlapping layers, at least one of which may comprise a cover.

A stent and a securely-installed artificial valve replacement device having the same, the stent being of a cylindrical structure; the top of the stent is provided with a fixed ear (60); the fixed ear (60) has a neck portion (601) connected to the top of the stent, and a head portion (602) engaged with the fixed head of the stent; the head portion (602) has a bending structure for improving the overall radial thickness; and the artificial valve replacement device is comprised of a stent and a prosthetic valve fixed on the stent. The stent with a bending structure overcomes the problem of easily disengaging from the fixed head of the stent, while not affecting the release of the stent.

A medical assembly implanting a transcatheter heart valve in the heart at a valve deployment site and related methods of implantation and delivery. An anchor is endovascularly introduced into the heart and implanted to a cardiac wall with an anchor delivery system and delivery cable. A second delivery system introduces a tether which coupled to the implanted anchor and a transcatheter heart valve. The transcatheter heart valve includes either a top or bottom brim which is positioned to conform to the atrial floor at the deployment site.

A method of replacing the function of a native heart valve is achieved by inserting a distal end portion of a delivery apparatus into a patient's body, wherein a prosthetic valve is disposed along the distal end portion of the delivery apparatus. The prosthetic valve includes a collapsible and expandable annular body having a network of struts interconnected at a plurality of nodes to form a plurality of open cells. Atrial and ventricular flanges are coupled to the annular body and extend radially away from the annular body. The annular body includes three commissure support posts of fixed length that extend substantially the entire length of the annular body. A valve member is secured to the commissure support posts. The annular body is radially expanded within the native heart valve and the atrial and ventricular flanges are deployed on opposite sides of the native heart valve.

A vascular stent, including an inner stent tube as well as a proximal support and a distal support which are arranged on an outer wall of the inner stent tube. When the vascular stent is in a compressed configuration, the proximal support and the distal support are both folded and close to the outer wall of the inner stent tube; when the vascular stent is expanded from the compressed configuration to an expanded configuration, a free end of the proximal support expands towards the distal end of the vascular stent, and a free end of the distal support expands towards the proximal end of the vascular stent. The vascular stent can be anchored to a main stent tube in a blood vessel by the proximal support and the distal support, preventing the vascular stent from shifting or becoming dislodged after being transplanted into the main stent tube.

A prosthetic heart valve device includes a valve support, a prosthetic valve assembly disposed within the valve support, and an anchoring member. The anchoring member includes a base attached to a first region of the valve support, a plurality of arm units projecting laterally outward from the base and inclined in a direction away from the first region in a deployed state, and a fixation structure extending from the arm units. Each arm unit includes a first portion coupled to the base and a second portion coupled to the fixation structure. The fixation structure includes a plurality of struts that define an annular engagement surface configured to press outwardly against a native annulus of a native heart valve. The first portion of each arm unit has a first flexibility greater that a second flexibility of the second portion of each arm unit.

Apparatus and methods are described including rotating at least a portion of a valve frame in a first direction and subsequently rotating the valve frame in a second direction. The valve frame includes chord-recruiting arms. An outer surface of each of the chord-recruiting arms has a smooth, convex curvature that extends along substantially a full length of the chord-recruiting arm, such that during the rotation of the portion of the valve frame in the first direction, the chords slide over the outer surface of the chord-recruiting arm without be recruited or caught by the chord-recruiting arm. An inner surface of each of the chord-recruiting arms has a concave curvature, such that during the rotation of the portion of the valve frame in the second direction, the chords are recruited within a space defined by the concave curvature.