The present invention relates to a new method for treating human or animal tissue such as cartilage, particularly damaged tissue. More specifically, the invention relates to a method to obtain material for treating the damaged tissue, for example any cartilage damage, in particular as a result of traumatic or degenerative cartilage damage.

Provided is a magnetically actuated microscaffold for minimal invasive osteochondral regeneration. More particularly, provided is a composition for cartilage regeneration, a microscaffold for cartilage regeneration, in which magnetic particles and cartilage regeneration cells are loaded on the surface of or within a 3-dimensional porous microstructure composed of a biodegradable polymer and having a diameter of 200-300 μm; and a microscaffold for bone regeneration, in which magnetic particles and bone regeneration cells are loaded on the surface of or within a 3-dimensional porous microstructure composed of a biodegradable polymer and having a diameter of 700-900 μm.

A fresh tissue allograft having at least one tissue portion maintained above a predetermined temperature to reduce the rate of cell death. A storage media having at least one free-radical scavenger is applied to the allograft to further slow the rate of cell death.

This disclosure is directed to a resilient interpositional arthroplasty implant for application into a joint to pad cartilage defects, cushion, and replace or restore the articular surface, which may preserve joint integrity, reduce pain and improve function. The implant may endure variable joint compressive and shear forces and cyclic loads. The implant may repair, reconstruct, and regenerate joint anatomy, and thereby improve upon joint replacement alternatives. The walls of this invention may capture, distribute and hold living cells until aggregation and hyaline cartilage regrowth occurs. The implant may be deployed into debrided joint spaces, molding and conforming to surrounding structures with sufficient stability so as to enable immediate limb use after outpatient surgery. Appendages of the implant may repair or reconstruct tendons or ligaments, and menisci by interpositional inflatable or compliant polymer arthroplasties that promote anatomic joint motion.

The present disclosure aims to provide a manufacturing method of a cell structure. The manufacturing method comprises a preparation step of preparing, on a culturing surface of a cell culture container, a first coated region coated with a temperature-responsive polymer and/or a temperature-responsive polymer composition, and a plurality of second coated regions located at an edge of the first coated region and coated with a cell adhesive substance; and a seeding and culturing step of seeding cells in the first coated region and the second coated regions and culturing the cells to produce a cell structure.

Volumetric muscle loss (VML) injuries characterized by critical loss of skeletal muscle tissues result in severe functional impairment. Current treatments involving use of muscle grafts are limited by tissue availability and donor site morbidity. The present application relates to methods and composition matters for skeletal muscle healing and regeneration for a patient with volumetric muscle loss using a glycosaminoglycan-based hydrogel, wherein said hydrogel for skeletal muscle regeneration comprises functionalized hyaluronic acid (HA), functionalized chondroitin sulfate (CS) and poly(ethylene glycol) diacrylate (PEGDA), wherein said HA and said CS are cross-linked by said PEGDA.

The present invention refers to a method of manufacturing an implantable construct comprising chondrogenically differentiated cells and one or more polycaprolactone (PCL) microcarriers, an implantable construct produced using said method, and uses of the implantable construct. The present invention also refers to a method of manufacturing an implantable construct comprising mesenchymal stromal cells and one or more polycaprolactone (PCL) microcarriers, an implantable construct produced using said method, and uses of the implantable construct. The present invention further refers to a method of treating a disease or disorder associated with cartilage and/or bone defect, the method comprises administering one or more cell-free polycaprolactone (PCL) microcarriers in a patient suffering from the disease or disorder.

The present application is directed to a method of treating osteoarthritis, which includes obtaining a member of a transforming growth factor superfamily of proteins; obtaining a population of cultured mammalian cells that may contain vector encoding a gene, or a population of cultured connective tissue cells that do not contain any vector encoding a gene; and then transferring the protein and the connective tissue cells into an arthritic joint space of a mammalian host, such that the activity of the combination within the joint space results in regenerating connective tissue.

This invention provides porated cartilage products and methods of producing porated cartilage products. Optionally, the cartilage products are sized, porated, and digested to provide a flexible cartilage product. Optionally, the cartilage products comprise viable chondrocytes, bioactive factors such as chondrogenic factors, and a collagen type II matrix. Optionally, the cartilage products are non-immunogenic.

A method is used for preparing a product for use in repairing a lesion or defect at a tissue site in a human or animal patient body. The method includes obtaining tissue from a donor human or animal body and freezing the obtained tissue. The method further includes pulverizing the frozen tissue and suspending the pulverized tissue in a fluid. The method further includes homogenizing the tissue suspension and precipitating tissue particles from the homogenized tissue suspension. The method further includes re-suspending the precipitated tissue particles and lyophilizing the tissue re-suspension to provide the product to be used in repairing the lesion or defect.