A device to be implanted in a subject's body to form an implant for replacing and/or increasing a volume of soft tissue, the device being of the type including a three-dimensional frame which defines an inner space in the frame. The frame is typically bio-absorbable and includes two side apertures forming a transverse passage for inserting a vascular pedicle. The device further has at least two bio-absorbable textile sheets that can be stacked on each other in the inner space of the frame.

An implantable prosthetic device, such as a breast implant, includes a shell made of a biocompatible elastomeric material. The shell has a front portion and a base that surround an interior volume of the shell. A scaffold is disposed within the interior volume of the shell. The scaffold has an inner surface facing the base and an outer surface facing the front portion of the shell. A silicone gel is disposed within the interior volume of the shell. The scaffold has a shape that mirrors the shape of the front portion of the shell. The scaffold reinforces the shell to provide form stability for maintaining the shape of the shell and minimizing folding, dimpling and/or wrinkling of the shell. A second scaffold may be nested within the first scaffold. The second scaffold has a smaller outer dimension than an inner dimension of the first scaffold.

A biocompatible membrane comprised of alginate and hyaluronate. The membrane may be used to prevent unwanted scarring after surgery. The tissue adherence and the rate of bioresorption of the membrane may be modified through an external stimulus comprising a sequestering agent and a viscosity modifier.

A porous implant for repairing lost bone stock such as around a prosthetic joint is provided. The porous implant has a composite structure with a solid structure and a porous structure which may be formed monolithically by direct metal laser sintering. The solid structure includes a support structure which extends into the porous structure.

A sheet structure comprising two joined extracellular matrix (ECM) tissue or sheet layers and a physiological sensor disposed therebetween; the ECM tissue being derived from a mammalian tissue source that includes small intestine submucosa (SIS), urinary bladder submucosa (UBS), stomach submucosa (SS), urinary basement membrane (UBM), liver basement membrane (LBM), amniotic membrane, mesothelial tissue, placental tissue and cardiac tissue.

A prosthetic heart valve including a frame, leaflet structure, and sealing member disposed around an outer surface of the frame is disclosed. As one example, the sealing member includes an inner layer and a plush outer layer comprising a plush outer surface. The inner layer is arranged against the outer surface of the frame and the outer layer is arranged against and attached to the inner layer. The inner layer is folded over at inflow and outflow ends, in an axial direction relative to a central longitudinal axis of the frame, to overlap respective ends of the outer layer and form tapered folds at opposite ends of the sealing member, each tapered fold including a narrower, first portion where the inner layer folds over and contacts itself and a wider, second portion where the inner layer overlaps an outer surface of an end portion of the outer layer.

Disclosed are apparatus, compositions, and methods for promoting regeneration of tissue on a subject such as a wounded, damaged, or injured appendage, or within a subject such as a wounded, damaged, or injured organ. The disclosed apparatus, composition, and methods include or utilize wearable sleeves and regenerative compositions.

A method and apparatus is provided for creating a modified tissue graft, wherein an anatomical site at which the modified tissue graft is to be placed is identified, desired characteristics for the modified tissue graft are identified based at least upon the anatomical site, one or more types of graft modifications and regions of the tissue graft to be modified are identified to achieve the desired characteristics; and at least a first area and a second area of the exterior surface of the tissue graft are modified by compressing, cutting and/or removing one or more portions thereof to create first designed surface features which cause the tissue graft to have first characteristics in the first area and second designed surface features which cause the tissue graft to have second characteristics in the second area.

Disclosed in the present disclosure is a prosthetic heart valve comprising a universal core which can be universally used in different implantation positions and different application scenarios, and an adapter selected from more than one adapters which are respectively suitable for the different application scenarios. The prosthetic heart valve according to the present disclosure has better flexibility and wider application range compared with various existing prosthetic heart valves, and may save time cost and research and development cost.

Cartilage support implants for nasal valve support and delivery systems are described. The cartilage support implant can include one or more elongate bodies comprising one or more anchors. The cartilage support implant can be designed to be a permanent implant extending along the midline of a patient's nose, from the nasal bone to the lower lateral cartilage. Methods of placing the cartilage support implant and retrieving the cartilage support implant are also described.