A surgical implant (100) comprises a mesh-like, flexible basic structure (104) having a center area and an outer periphery (120), wherein the outer periphery (120) has a polygonal shape with N corners (122), N being at least 3. The implant (100) may comprise at least two pockets (124), each pocket (124) extending from a peripheral line which connects two corners (122) of the outer periphery (120) of the basic structure (104) towards the center area of the basic structure (104). The center area of the basic structure (104) can be marked by a center marking (130), wherein directional indicators (132) point from the center marking (130) to at least two corners (122) of the outer periphery (120) of the basic structure (104).

A two dimensional (2D) active plasmonic scaffold includes a polymer film and one or more nanoparticle layers disposed on the polymer film. The nanoparticles has functional groups attached thereon. A three dimensional (3D) structure fabricated using the 2D scaffold.

Novel stay suture devices and stay suture combinations with meshes are disclosed. The stay suture devices have a clip and a suture. The clip has leg members that are mounted to a hernia mesh implant such that the leg members are locked in a closed configuration. Also disclosed are novel methods of mounting stay sutures to a surgical mesh implant and repairing a body wall defect such as a hernia defect.

A novel single plane tissue repair device such as a patch is disclosed. The device has a base member with an opening therethrough, and a closure member associated with the opening. The mesh has a biaborbable polymeric adhesion barrier attached to the bottom side of the base member about its periphery to form a pocket that is accessible through the opening. The mesh may be used in open surgical procedures for hernia repairs and other repairs of body wall defects.

A novel single plane tissue repair patch is disclosed. The patch has a base member with an opening therethrough, and a closure member associated with the opening. Mounted to the periphery of the bottom side of the base member is a locating structure. The mesh may be used in open surgical procedures for hernia repairs and other repairs of body wall defects.

An implantable mesh for use in reconstructing tissue includes a mesh body and one or more extensions extending from the mesh body. Each mesh extension has a first end and a second end, wherein the first end of the mesh extension is integrated into or part of the mesh body. Each mesh extension is configured to permit multiple anchor points with surrounding tissue upon implantation. In one embodiment, a fixation device is at the second end of each mesh extension. Methods of using the implantable mesh are also provided.

A medical device including a mesh prosthesis having a first mesh layer affixed to a second mesh layer along a perimeter area. An enclosure is defined between the first and second layers and extends inwardly from the perimeter area. An opening in the first layer passes through the first layer to the enclosure. A fixation guide template defines a guide pocket within the enclosure. A resilient deployment structure is removably disposed within the enclosure and extending toward the perimeter area. The resilient deployment structure has an elasticity that generates a resilient deployment force for urging the mesh prosthesis to a deployed configuration from a non-deployed configuration. A shield projection extends outwardly from a perimeter of the resilient deployment structure and is engaged within the guide pocket to prevent relative rotational movement between the resilient deployment structure and the mesh prosthesis. A method of using a medical device is also included.

Formulations of shape memory polymer (SMP) are integrated with several existing clinically available medical fabrics. The SMP portion of a SMP integrated fabric can be fabricated in varying thicknesses with the minimum thickness determined by the thickness of the underlying fabric and up to almost any thickness. Integration of the SMP with the base fabrics does not alter the shape memory functionality of the SMP. The design tools for controlling activation rate for traditional SMP materials thus apply to SMP integrated fabrics. SMP integrated fabrics may also be steam sterilized without loss of shape memory functionality.

A suture-less pelvic implant system and method is provided for treating pelvic conditions, such as incontinence or vaginal prolapse. The implant can include a fixation portion, which may be rectangular or suture line, having a plurality of fixation elements, e.g., barbs, extending therefrom to fixate within target pelvic tissue, such as the vaginal apex. In a sacralcolpopexy, an opposing end or anchor of the implant is fixated within the sacrum or like structure to stabilize, raise, support or reposition the vaginal apex.

A space in a muscle wall such as the inguinal canal is dilated by a plunger-based mechanism to break up fibrotic bands by divulsion. While the space is dilated a dynamic plug is advanced into it, with the plug expanding and contracting with the space.