A bioadhesive sheet-shaped material configured to be attached onto a surface of an organ, a method for producing the bioadhesive sheet-shaped material, and a method for treating a disease by using the bioadhesive sheet-shaped material. The bioadhesive sheet-shaped material includes an extracellular matrix layer, a sheet-shaped cell culture, and a biodegradable gel layer, where the sheet-shaped cell culture is interposed between the extracellular matrix layer and the biodegradable gel layer, and the bioadhesive sheet-shaped material is by attaching the extracellular matrix layer onto a surface of an organ.

The present invention pertains to novel bone graft substitute materials. These materials are porous, homogenously dispersed solid mixtures of calcium phosphate and pro-regenerative extracellular matrix (ECM)—and potentially any pharmaceutical agent and/or mineral—that have been infused with polydopamine. In some embodiments the bone graft materials have osteoinductive factors incorporated within them.

A viable disc regenerative composition has a micronized material of nucleus pulposus and a biological composition made from a mixture of mechanically selected allogeneic biologic material derived from bone marrow having non-whole cellular components including vesicular components and active and inactive components of biological activity, cell fragments, cellular excretions, cellular derivatives, and extracellular components; and wherein the mixture is compatible with biologic function and further includes non-expanded whole cells. The biological composition is predisposed to demonstrate or support elaboration of active volume or spatial geometry consistent in morphology with that of disc tissue. The viable disc regenerative composition extends regenerative resonance that compliments or mimics disc tissue complexity.

A method of treating a lesion in a gastrointestinal tract and an injectate system are provided. The method includes injecting a crosslinkable gel into a first tissue layer, the crosslinkable gel increasing a volume of the first tissue layer. The method also includes providing a crosslinker and resecting a portion of a first tissue layer having the increased volume away from a second tissue layer creating an exposed region in a remaining portion of the first layer and leaving a portion of the gel covering at least a portion of the exposed region. The injectate system includes a crosslinkable gel and a crosslinker where the crosslinkable gel and the crosslinker form a crosslinked gel having a compressive modulus of about 10-500 kPa.

The invention relates to a method of producing a decellularized tissue scaffold. The invention also relates to a tissue scaffold produced by said method. In particular, porcine tissue scaffolds. The method comprises reduced levels of anionic detergent, and avoids the use of animal derived protease inhibitors to produce a tissue scaffold with favourable properties.

Disclosed are a functionalized biological matrix material, a preparation method therefor and use thereof, which belong to the technical field of medical materials. In the present invention, by means of the hybridization of a biological matrix material with 3-sulfopropyl methacrylate, the cross-linking and functionalization of the biological matrix material are achieved at the same time. A specific method comprises modifying carbon-carbon double-bond structures such as allyl, methallyl in a biological matrix material, immersing the biological matrix material in an aqueous solution containing 3-sulfopropyl methacrylate, and finally performing cross-linking and functionalization on the biological matrix material by means of radical polymerization, and using the biological matrix material to prepare materials such as valves. The present invention achieves multi-site and long-range cross-linking of a biological matrix material by means of a polymer network, and at the same time introduces corresponding functional functional groups so as to achieve functionalization of the biological matrix material.

The present disclosure describes a composition for cartilage defects or deficiencies repair, augmentation or treatment comprising an injectable, in situ polymerizable collagen composition and chondrocytes or stem cells in the collagen composition. The present disclosure also relates to methods for repairing or augmenting or treating cartilage defects or deficiencies using the composition and the preparation method of the composition.

Methods are disclosed for dissecting a mucosa and a submucosa from a muscularis propria from a region of an esophagus of a subject. These methods include injecting submucosally into the esophagus of the subject a pharmaceutical composition comprising an extracellular matrix (ECM) hydrogel to form a cushion between the submucosa and the underlying muscularis propria at the region of the esophagus, wherein the ECM hydrogel has the following characteristics: a) a time to 50% gelation of less than 30 minutes at a temperature of about 37° C.; b) a flow viscosity suitable for infusion into the esophagus; and c) a stiffness of about 10 to about 400 Pascal (Pa). The ECM hydrogel is not a urinary bladder ECM hydrogel.

A bone implant comprising cancellous bone that is essentially free of blood cells, and which has been treated with at least a loosening agent, such as collagenase and/or a digestive enzyme, for a time and at a concentration to loosen the osteogenic cells in the cancellous bone matrix. The osteogenic cells in the matrix are viable cells. The treatment of the cancellous bone with at least one loosening agent enables the osteogenic cells to be more available for carrying out their osteogenic function and to provide for an increased rate of bone formation.

An injectable composite material for bone repair comprises a biological tissue material and bioceramics in order to serve as a three-dimensional scaffold for bone regeneration. The biological tissue material consists of microfibers having a naturally cross-linked structure without additional physical or chemical cross-linking, has superior biological compatibility, and can be slowly and completely degraded in vivo. The bioceramics in the composite material serves as a reinforcing phase. When combining the biological tissue material with the bioceramics, the composite material provides a template for bone tissue regeneration to effectively induce bone growth. The injectable composite material for bone repair can be used to fill bone defects, particularly critical-sized bone defects, and can be combined with a biological agent such as bone marrow to improve its biological activity. Therefore, the composite material can be widely used to repair bone defects caused by trauma, tumor resection, osteonecrosis, and infection.