A prosthesis for repairing a hernia defect includes a patch body, a hoisting frame releasably attachable to the patch body, and a tether attached to the hoisting frame with a free end extendable through the thickness of the patch body and accessible from the side of the patch body opposite to where the hoisting frame is releasably attached. The patch body and/or the hoisting frame includes a self-expanding support member. The hoisting frame includes a frame body with an outer frame component and a force translation component for directing pulling forces on the tether across the frame body. The outer frame component has a loop configuration to generally follow the patch periphery with overlapping end portions or a gap between free ends thereof. The force translation component is separable into multiple segments to facilitate withdrawal of the hoisting frame through an opening when released from the patch.

The present disclosure relates to a medical anchor device and methods of use for providing an improved device for intraluminally directed vascular anastomosis. The anchor device includes a generally tubular graft having a flange disposed at one end thereof, where a portion of the graft extends through the flange. The flange includes a wire frame made of a resilient material and a thin membrane covering or overlaying the wire frame, where the wire frame is self-expanding when deployed within a lumen. The device may be deployed within the lumen at an anastomotic site without a need for sutures, staples, clips, or other mechanical attachment means that may cause further injury.

The present teachings provide a device and methods of making and using thereof. Specifically, one aspect of the present teachings provides a self-expandable device with a braided structure comprising a shunt, a distal retention flange, and a proximal retention flange. Upon the device being deployed at a treatment location, the distal retention flange or the proximal retention flange transitions to have a diameter that is greater than the diameter of the shunt portion. And the shunt portion has a braid angle . Another aspect of the present teachings provide that the ratio of flange/shunt diameter equals or greater than 1/sin . Yet another aspect of the present teachings provides an axial constraining mechanism to reinforce the shunt portion.

A stent including a tubular body formed of one or more interwoven wires, a first anchor member disposed adjacent the first open end of the stent, a second anchor member disposed adjacent the second open end of the stent, and at least one divider disposed between the first and second anchor members. The first and second anchor members and the divider extend radially outward from the tubular body to divide the tubular body into at least a first saddle region extending between the first anchor member and the divider and a second saddle region extending between the second anchor member and the divider.

There is provided herein a supra mitral device for mitral/tricuspid valve repair in a subject in need thereof, the device comprising: a main body portion having essentially annular D-shape with an eccentric opening, such that a posterior section of said main body portion is wider than an anterior section of said main body portion, said posterior section of said main body portion configured for coverage and attachment to essentially the whole section of the posterior leaflet of the mitral valve which faces the left atrium on systole, thereby preventing and/or reducing mitral regurgitation, wherein said posterior section of said main body portion is made of a pliable material, adapted to stiffen after implantation of the device.

A cardiac device comprises a first anchoring element configured to be attached to a first side of a tissue wall, a second anchoring element configured to be attached to a second side of the tissue wall, and a cinching device. The cinching device is configured to attach to the first anchoring element and the second anchoring element and apply force to the first anchoring element to move the first anchoring element towards the second anchoring element and at least partially compress the tissue wall.

Systems, apparatuses, and methods disclosed herein are provided for medical treatment, including transcatheter medical treatments and/or for treatment of dilated hearts (e.g., dilated left ventricle) or functional mitral valve regurgitation within a human heart. The systems, apparatuses, and methods disclosed herein may include applying one or more heart splints to the patient's heart to apply pressure to the heart to reshape the heart. Anchors disclosed herein may be utilized in plugs for treating openings in a septum between two chambers of a heart, e.g., ventricular septal defects (VSD), atrial septal defects (ASD), and patent foramen ovale (PFO). In addition, the anchors disclosed herein may be utilized to reshape an annulus of a patient's heart valve, including a tricuspid valve of a patient's heart. The anchors disclosed herein may also be utilized to reposition a heart valve leaflet to reduce heart valve leaflet prolapse.

A hair implant suitable for subcutaneous implantation is provided having an anchor comprising an anchor body, and at least one collagen receiving structure selected from the group consisting of at least one tunnel disposed through the anchor body and an external surface feature of the anchor body. The anchor further comprises at least one hair strand projecting from a distal end of the anchor body, wherein the at least one collagen receiving structure is configured to support collagen ligature growth after subcutaneous implantation of the hair implant so as to anchor the anchor to a hair implant recipient, and the collagen receiving structure is free of hair. A fracture line in the anchor body allows the body to fragment, thereby releasing collagen ligatures and allowing the implant fragments to release and fall out of the skin. The at least one hair strand may comprise a primary hair element with emerging hair elements.

A stent has a center length section, two end sections, and an elastically deformable woven wire mesh, which enables the stent to expand from a small diameter to a larger diameter, with the diameter of the end sections being larger than in the center length section in the expanded state. The wire extends in a zig-zag manner from an outer end of one end section toward the outer end of the other end section, and back in a zig-zag manner to the one end section. The peripheral direction of the woven wire changes at the transition from an end section to the center length section, such that the wire intersects on the return path to the one end section in the center length section and overall forms an 8-shaped loop having two closed eyes, wherein a plurality of interconnected loops are arranged offset to each other over the circumference.

The package (1) for a surgical mesh (100) comprises: a receiving member (2) configured and dimensioned to receive at least one surgical mesh (100), and a covering member (3) configured and dimensioned to cover the said at least one surgical mesh (100) maintaining with the receiving member (2) the surgical mesh (100) in a substantially flat position, and a gas channelling network interposed between the said receiving member (2) and the said covering member (3) configured to channel a sterilization gas within the at least one surgical mesh (100).