The present disclosure relates to tissue matrix products. The products can includes tissue matrices that have holes or perforations located at certain positions to improve certain in vivo functions without substantial loss of strength or other important properties.

The present invention relates to a method for manufacturing a hemocompatible material comprising a synthetic substrate and animal biological tissue, according to which said animal biological tissue is dehydrated and adhered to said synthetic substrate by means of a dispersion of the material forming said synthetic substrate. According to the invention, the animal biological tissue is only dehydrated chemically by immersing said animal biological tissue in a bath consisting of a solution containing at least 80 wt % of polyethylene glycol.

A problem to be solved by the present invention is to provide a fibrosis inhibitor that solves the problem of inhibiting fibrosis of an organ or tissue surface, and especially of inhibiting fibrosis of an epicardial surface. Furthermore, by inhibiting fibrosis, the present invention prevents or reduces subsequent development of adhesions to avoid organ or tissue damage during re-operation. Provided is a fibrosis inhibitor for inhibiting fibrosis of a tissue by fixing a biocompatible polymer to a tissue where it is desirable to inhibit fibrosis.

Osteoinductive compositions and implants having increased biological activities, and methods for their production, are provided. The biological activities that may be increased include, but are not limited to, bone forming; bone healing; osteoinductive activity, osteogenic activity, chondrogenic activity, wound healing activity, neurogenic activity, contraction-inducing activity, mitosis-inducing activity, differentiation-inducing activity, chemotactic activity, angiogenic or vasculogenic activity, and exocytosis or endocytosis-inducing activity. In one embodiment, a method for producing an osteoinductive composition comprises providing partially demineralized bone, treating the partially demineralized bone to disrupt the collagen structure of the bone. In another embodiment, an implantable osteoinductive and osteoconductive composition comprises partially demineralized bone, wherein the collagen structure of the bone has been disrupted, and, optionally, a tissue-derived extract.

The invention provides a plasticized tissue or organ that does not require special conditions of storage, for example refrigeration or freezing, exhibits materials properties that approximate those properties present in natural tissue, is not brittle, does not necessitate rehydration prior to clinical implantation and is not a potential source for disease transmission. Replacement of the chemical plasticizers by water prior to implantation is not required and thus, the plasticized bone or soft tissue product can be placed directly into an implant site without significant preparation in the operating room.

In some embodiments, the present disclosure pertains to a method of fabricating an artificial heart muscle (AHM) patch. In some embodiments, the method includes obtaining and/or isolating cells from a subject. In some embodiments, the cells are primary cardiac cells. In some embodiments, the method further includes forming a scaffold. In some embodiments, the method includes seeding the cells in the fibrin gel scaffold. In some embodiments, the method includes culturing the cells seeded in the fibrin gel scaffold under conditions appropriate for the formation of an artificial heart muscle (AHM) patch. In some embodiments, the present disclosure pertains to a method of fabricating a bioartificial heart (BAH). In some embodiments, the present disclosure pertains to a method of treatment of cardiac tissue injury in a subject in need thereof. In some embodiments, the method includes implanting the aforementioned artificial heart muscle patch in the injured area of the subject. In some embodiments, the present disclosure relates to a method of treating end stage cardiac disease in a subject in need thereof.

This document relates to decellularized nerve allografts. For example, decellularized nerve allografts and methods and materials for using decellularized nerve allografts to repair nerve injuries or bridge a severed nerve are provided.

A composition includes a dual crosslinkable hydrogel that includes a plurality of polymer macromers, which are crosslinked with a first agent and a second agent different than the first agent, wherein the crosslinks formed using the second agent are reversible and repeatable to allow the mechanical properties of the hydrogel to be dynamically adjusted.

The present invention describes a process for obtaining extracellular matrix from the skin of tilapia (Oreochromis niloticus) comprising the steps of chemical and enzymatic decellularization, detoxification, chemical disinfection, crosslinking, bleaching, dehydration and sterilization by gamma radiation, more specifically the steps comprised by each of said procedures and use of the extracellular matrix for treating ruptured of tissues, dermatitises, acute, chronic and traumatic lesions, battlefield wounds, necrotic wounds, lacerations, abrasions, bruises and other lesions and conditions. The present invention falls within the fields of pharmacy, medicine and veterinary medicine, dentistry, chemistry, tissue engineering, molecular biology and biotechnology.

A method for manufacturing an animal acellular tissue matrix material and a tissue matrix material manufactured by the same. The tissue matrix material manufactured by the method retains an original basic scaffold structure of a tissue extracellular matrix, with an antigen causing immunological rejection in a human body being effectively removed from the animal tissue. An animal dermal matrix manufactured by the method retains the biological integrity of a natural dermal tissue matrix and can be used for restoration and repair of lesion and missing tissues.