The present invention relates to a mesh or membrane covering (2) based on biological material, for example collagen, or biosynthetic material for prostheses (1), in particular for a breast prosthesis (1), said prosthesis (1) having a rear surface that, when applied, is faced towards the person on whom (1) is applied, said covering (2) being characterized in that it provides a fixing system (4; 3) for fixing to said prosthesis (1), said fixing system providing a plurality of teeth or petals (4) or outer perimeter edge foldable on said rear surface of the prosthesis (1) by means (5). The invention further relates to a method for fixing said covering to a prosthesis, a prosthesis comprising said covering and a process for making said covering.

A biological product for clinical xenotransplantation into a human and a method of preparing biological product for clinical xenotransplantation into a human involving producing a non-wild type, biologically engineered swine having a biologically engineered genome such that the swine does not express one or more extracellular surface glycan epitopes, is free of certain pathogens, is reared according to a bioburden-reducing procedure in a closed designated pathogen free herd, wherein the biological product is harvested following the swine being euthanized and the product is aseptically removed from the swine, the biological product is processed involving sterilization and storing the product in a sterile container, and the product does not contain one or more extracellular surface glycans, is free of certain designated pathogens, is biologically active and comprises live cells and tissues capable of vascularizing after xenotransplantation.

The present application is directed to the field of implants comprising soft tissue for use in implantation in humans. The soft tissue implants of the present application are preferably obtained from xenograft sources. The present application provides a chemical process that sterilizes, removes antigens from and/or strengthens xenograft implants. The present techniques yield soft tissue implants having superior structural, mechanical, and/or biochemical integrity. The present application is also directed to processes for treating xenograft implants comprising soft tissues such as dermis, and to implants produced by such processes.

The present disclosure relates to tissue matrix products. The products can include tissue matrices that have openings such as holes or perforations located at certain positions to improve various functions without substantial loss of strength or other important properties. The openings can facilitate implantation of the tissue matrices in surgical procedures thereby speeding operation times and potentially improving surgical results.

The present invention provides a method for manufacturing a regular and high-density regenerated hair follicle primordium aggregation similar to the hair follicle tissue of a mammal in a simple manner. A regenerated hair follicle primordium aggregation manufacturing method of the present invention includes a step of forming hair follicle primordia by inoculating a microwell plate, which includes regularly arranged microwell portions, with mesenchymal cells and epithelial cells and culturing a mixture of the cells while supplying oxygen thereto.

Provided is a system and method for providing a non-binding allograft subtalar joint implant for surgical implant into a person's foot proximate to the ankle. This system for repair includes at least one sterile non-binding allograft subtalar joint implant provided as a pre-formed allograft rod plug ARP having a diameter about equal to an average width of a canal between a person's talus and calcaneus bones, the ARP being resiliently compressible and flexible. When snuggly disposed between the person's talus and calcaneus bones, the ARP compresses during normal use of the person's foot and maintains the canal in an anatomically correct alignment and reduces a tendency for abnormal motion between the person's talus and calcaneus bones. An associated method of use is also provided.

Disclosed herein are muscle implants and methods of making muscle implants comprising one or more decellularized muscle matrices. The muscle matrices can, optionally, be joined to one or more decellularized dermal matrices. The muscle implants can be used to enhance muscle volume or to treat muscle damage, defects, and/or disorders. The decellularized muscle matrices in the implants retain at least some of the myofibers found in a muscle tissue prior to processing.

The present application relates to injectable tissue products and their production and use thereof. The tissue products include a group of acellular tissue matrix particles, a bioadhesive, and a biocompatible polymer. The tissue products may be used to treat hernia defects.

The present invention relates to a built-in bio-sleeve and preparation method and use thereof. In order to provide a suitable built-in bio-sleeve material for dorsal nerve isolation surgery and penis enlargement surgery, a novel acellular allogeneic dermal matrix material is prepared in the present invention, which is manufactured into a built-in bio-sleeve for the treatment of premature ejaculation and short and small penis. The acellular allogeneic dermal matrix or the built-in bio-sleeve of the present invention is used for dorsal nerve isolation surgery, penis enlargement or lengthening surgery without cutting off the dorsal nerve, thereby avoiding the probability of psychological erectile dysfunction caused by the patient's worry about cutting off the dorsal nerve.

A method of producing a modified acellular tissue matrix (mATM) from an acellular tissue matrix (ATM), where the mATM has a reduced stretchiness relative to the ATM, without substantially compromising its associated structural or functional integrity. The method includes providing an acellular tissue matrix (ATM) and exposing the ATM to elastase for a period of time.