Methods of forming topographical features on an article, for example on a medical devices that has a surface configured to promote the migration of cells onto the surface of the medical device. In particular, the resulting surface of the medical device has a noncontiguous pattern of topographical features formed therein or thereon.

A tympanic membrane prosthesis includes a tubular body having a lumen extending therethrough and open at each of a proximal and distal end. The tubular body forms a structurally self-supporting, body compatible, and body absorbable device. The device is formed of a composite structure that includes an inner portion having an inside surface and an outer portion having an outside surface. The inside surface forms at least a portion of the lumen extending through the tubular body. The inside surface is adapted to provide less resistance to fluid flow than the outside surface. The outside surface is adapted to produce an inflammatory reaction in adjacent tissue at a tympanic membrane. The device is adapted for insertion into an opening through the tympanic membrane for placement with the proximal end and the distal end disposed on opposite sides of the tympanic membrane.

The Nucleo-reticular Multi-cell Dual-system Eye Implant consists of a spherical structure with calculated and variable axial length depending on the needs required by the orbital eye socket, composed of a cell mesh with alternative designs that in turn, makes up the MMM System, in which suturing is provided in any technique, either in cases of evisceration or enucleation. Thanks to its multi-cell structural design, it favors its placement and reduces the risk of migration, extrusion, exposure and extraction. As it is an arrangement with structural holes, it provides a higher percentage of the volume for its vascularization; it also houses inside a Reticular Fibrovascular Core System, which has a structure based on multilevels equipped with micro-reticular tissue and an intra-level communication based on filaments; with the capacity to contain medicines and/or technology by presenting a dual-system of two screw-on pieces, being able to manufacture in different structural designs and biocompatible materials. The C100 model made of polylactic acid (PLA), an ideal material for implants, consists of 100 oval cells. Since it is a light eye implant, it prevents depressure due to settlement or gravity and it can be manufactured in any size.

Certain aspects of the present disclosure provide a flexible scaffold implant comprising a plurality of layered structures, the plurality of layered structures comprising: a first layered structure having a three-dimensional (3D) shape and formed from a bioresorbable material, and a second layered structure conforming to the corresponding 3D shape of the first layered structure and formed from the bioresorbable material. The first layered structure is arranged in proximity to the second layered structure. The first layered structure is configured to dissolve for resorption at a different rate than the second layered structure based on design elements of the first layered structure and the second layered structure. The plurality of layered structures are flexible.

A delivery device (1) for an endoprosthesis (2). The endoprosthesis (2) is preferably an endoprosthesis for treating an aneurysm. The delivery device (1) comprises an outer sheath (3) and an inner tube (4). The inner tube (4) is arranged within the outer sheath (3) and at least one restraining tube (5, 30). The restraining tube (5, 30) is for holding the endoprosthesis (2) in a compressed configuration. The restraining tube (5, 30) is arranged between the outer sheath (3) and the inner tube (4). The outer sheath (3), the inner tube (4) and at least one restraining tube (5, 30) are coaxial. The restraining tube (5, 30) includes at least one axial elongation (6) extending from a distal end portion of the restraining tube. The at least one axial elongation (6) is adapted to be laced through portions of the endoprosthesis (2).

A mesh implant is disclosed and comprises a single sheet, highly porous, adhesion-resistant, tensile surgical implant composed of a gradually biodegradable synthetic polymer material that is electrospun into nanofibers and randomly stacked to form a three-dimensional (3D) mesh. The mesh implant is for tissue repair and hernia repair. The single-sheet design reduces the foreign material that make up the mesh implant, which minimizes mesh implant rejection. The gradually biodegradable nature of the mesh implant guarantees that the mesh stays in place and supports the repaired site long enough until a proper scar tissue has built up, after which the mesh implant disappears from the body, therefore preventing pain and irritability. The 3D design of the nanofibrous network and the high porosity of the mesh implant facilitate cell attachment, infiltration, and proliferation, all necessary for scar tissue formation, mesh integration, wound healing, and proper defect closure.

The invention relates to an artificial vascular graft comprising a primary scaffold structure encompassing an inner space of the artificial vascular graft, said primary scaffold structure having an inner surface facing towards said inner space and an outer surface facing away from said inner space, a coating on said inner surface, wherein a plurality of grooves is comprised in said coating of said inner surface. The primary scaffold structure comprises further a coating on said outer surface. The primary scaffold structure and the coating on said inner surface and on said outer surface are d designed in such a way that cells, in particular progenitor cells, can migrate from the periphery of said artificial vascular graft through said outer surface of said coating, said primary scaffold structure and said inner surface to said inner space, if the artificial vascular graft is used as intended. The invention relates further to a method for providing said graft.

Soft tissue grafts, packaged soft tissue grafts, and methods of making and using soft tissue grafts are disclosed. One soft tissue graft includes processed tissue material having first and second opposed surfaces. The first and second opposed surfaces are bounded by first and second edges. The first edge has a concave shape that curves toward the second edge. The second edge has a convex shape that curves away from the first edge. The first surface comprises a plurality of apertures. At least one of the apertures is formed from a multi-directional separation in the first surface. One method of making a soft tissue graft includes positioning a cutting die on a surface of tissue material, pressing the cutting die into the tissue material to cut the tissue material, and processing the cut tissue material to create processed tissue material.

A soft breast prosthesis is provided, the prosthesis having a surface configuration advantageous for dual plane placement of the prosthesis in a breast.

A full-function artificial organ fitting body comprises a cortex layer and an organ body tissue area. The organ body tissue area comprises a growth area, a differentiation area, a docking area, a branch arterial system, a branch nervous system and a branch venous system. The branch arterial system, the branch nervous system and the branch venous system are distributed in the differentiation area and form a main body three-dimensional skeleton structure with the outer growth area and the middle docking area.