The present invention is a method for producing allograft tissue by applying an antimicrobial solution to allograft tissue. The antimicrobial solution exhibits antimicrobial activity to make allograft resistant to microbial organisms, such as bacterium.

The present invention relates to a monolithic multi-layered material having at least a first layer, from which anisotropic pores originate, and a second layer, in which the anisotropic pores continue. The present invention further relates to a monolithic medical material having at least a first layer, from which anisotropic pores originate, and a second layer, in which the anisotropic pores continue. The present invention further relates to a process for the production of a multi-layered material having anisotropic pores. It further relates to a multi-layered material which can be produced by the process according to the invention.

An improved device and method for extended repair and regeneration of muscle tissue. An exemplary device comprises (a) a scaffold comprising an ECM component; (b) a combination of growth factors such as VEGF and IGF; and (c) a population of myogenic cells. Implantation of the device leads to muscle regeneration and repair over an extended period of time.

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.

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.

The invention provides a device, a kit for repairing and fixing articular cartilage, and a method for the same. The device comprises a costal cartilage rod, an outer sleeve, a drilling part, and an auxiliary implantation component; the drilling part comprises a drill sleeve and a drill bit matching an inner diameter of the drill sleeve; the auxiliary implantation component comprises a cartilage rod sleeve and an auxiliary pushing element, the costal cartilage rod has a rod-shaped structure with a diameter ranging from 3 mm to 8 mm and less than an inner diameter of the cartilage rod sleeve, and the costal cartilage rod is obtained from processing of costal cartilage. The costal cartilage is selected from the group consisting of autologous costal cartilage, allogeneic costal cartilage, or xenogeneic costal cartilage. Costal cartilage is processed into a costal cartilage rod by using the device provided in the present invention.

The invention provides a method of making a biological disc graft. In one embodiment, the biological disc graft is useful for treating back or neck pain. In one embodiment, the biological disc graft is useful for treating any joint pain. The invention also provides a method of implanting said biological disc graft in a way that is minimally invasive and less dangerous.

The present disclosure provides surgical implants that are useful for nipple-areola complex (NAC) or facial reconstruction in a subject, and methods for fabricating and using the same. The surgical implants of the present technology comprise minced or zested cartilage that is encaged by an external biocompatible scaffold.

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.

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.