A method for use of a double-structured tissue implant or a secondary scaffold stand-alone implant for treatment of tissue defects. The double-structured tissue implant comprising a primary scaffold and a secondary scaffold consisting of a soluble collagen solution in combination with a non-ionic surfactant generated and positioned within the primary scaffold. A method of use of a stand-alone secondary scaffold implant or unit for treatment of tissue defects.

Systems, devices, and methods for reducing regurgitation through an atrioventricular heart valve: i.e., the mitral valve and the tricuspid valve. The device includes a flexible anchor rail anchored in the tissue of the ventricle and an offset coaptation element on a catheter that rides over the anchor rail and is positionable between the valve leaflets. The proximal end of the coaptation catheter is fixed subcutaneously adjacent the subclavian vein. The coaptation element includes an inert covering over a foam interior, and is radially offset on the catheter so that the foam body projects away from the septal side of the valve to reduce or minimize deformation from contact with the septal wall of the ventricle. Markers on the coaptation element facilitate positioning in the desired rotational orientation during delivery and implant.

In a representative embodiment, an implantable assembly for a native heart valve comprises a prosthetic heart valve and first and second inflatable bodies. The prosthetic heart valve can comprise a frame and prosthetic leaflets. The first inflatable body can comprise first and second end portions, wherein the first end portion is configured to be secured to tissue of the native heart valve at a first location, and the second end portion is configured to engage an outer surface of the prosthetic valve. The second inflatable body can comprise third and fourth end portions, wherein the third end portion is configured to be secured to tissue of the native heart valve at a second location, and the fourth end portion is configured to engage the outer surface of the prosthetic valve. The first and second inflatable bodies anchor the prosthetic valve within the annulus of the native heart valve.

Systems, devices and methods for repairing a native heart valve. In one embodiment, a repair device for repairing a native mitral valve having an anterior leaflet and a posterior leaflet between a left atrium and a left ventricle comprises a support having a contracted configuration and an extended configuration. In the contracted configuration, the support is sized to be inserted under the posterior leaflet between a wall of the left ventricle and chordae tendineae. In the extended configuration, the support is configured to project anteriorly with respect to a posterior wall of the left ventricle by a distance sufficient to position at least a portion of the posterior leaflet toward the anterior leaflet.

A storable molded body is made of treated bacterial cellulose. The treated bacterial cellulose is dry and has a swelling capacity that is greater than untreated bacterial cellulose of the same type. The swelling capacity of the treated bacterial cellulose can be between about 103% and 154% greater than the non-treated bacterial cellulose. The bacterial cellulose can be from Gluconacetobacter xylinus. An implant includes or consists of the molded body of treated bacterial cellulose.

The present disclosure relates to valve replacement devices that are foldable for catheter-based deployment to the site of implantation, as well as systems for the delivery of valve prostheses, including prostheses having the special characteristics of the disclosed valve replacement devices. The devices include highly effective adhering mechanisms for secure and enduring precision implantation. The adhering mechanisms may employ a unique sealing mechanism that includes a cuff that expands slowly whereby the device is not secured in place until the completion of the implantation procedure. The implanted device, optionally together with the cuff, prevents perivalvular leaks and incorporate an appropriate leaflet system for reliable functioning in situ.

Devices and methods for inserting an implant into skin or other tissue of a patient can include a hyaluronic thread that is coupled at along distal portion with an insertion device. The insertion device can include a cover member and a piston that can collectively facilitate engagement with or disengagement of the distal portion of the thread with the device. For example, the piston can be positioned within an inner cavity of the cover member, and the distal portion of the thread can be engaged by and/or between the piston and the cover member. The thread can be released by movement of the piston relative to the cover member. Thus, some insertion devices can grasp or engage the distal portion of the thread and push the distal portion thread into and through into skin or other tissue of a patient.

Systems, devices and methods for repairing a native heart valve. In one embodiment, a repair device for repairing a native mitral valve having an anterior leaflet and a posterior leaflet between a left atrium and a left ventricle comprises a support having a contracted configuration and an extended configuration, and an appendage, such as a flap or apron extending from the support. In the contracted configuration, the support is sized to be inserted under the posterior leaflet between a wall of the left ventricle and chordae tendineae. In the extended configuration, the support is configured to project anteriorly with respect to a posterior wall of the left ventricle by a distance sufficient to position at least a portion of the posterior leaflet toward the anterior leaflet, and the appendage is configured to extend beyond an edge of the posterior leaflet toward the anterior leaflet.

The present technology relates generally to endovascular prostheses. More particularly, the disclosure relates to endovascular prostheses having an outer surface of a graft material thereof associated with a hydrogel composition, which may swell upon implantation within a blood vessel, thereby mediating various complications associated with endovascular procedures. The hydrogel compositions can also include various stabilizing polymers and active agents to further aid their use in the body.

A composite scaffold having a highly porous interior with increased surface area and void volume is surrounded by a flexible support structure that substantially maintains its three-dimensional shape under tension and provides mechanical reinforcement during repair or reconstruction of soft tissue while simultaneously facilitating regeneration of functional tissue.