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.

A method for use of a double-structured tissue implant or a secondary scaffold stand-alone implant for treatment of tissue defects. The double-structured tissue implant comprising a primary scaffold and a secondary scaffold consisting of a soluble collagen solution in combination with a non-ionic surfactant generated and positioned within the primary scaffold. A method of use of a stand-alone secondary scaffold implant or unit for treatment of tissue defects.

The subject invention pertains to a decellularized stem cell sheet and compositions thereof with retained biological activity. The present invention further relates to the optimized method of producing the decellularized stem cell sheet and methods of using the decellularized stem cell sheet for the promotion of tissue repair in a subject.

Disclosed herein are methods of producing a cartilaginous implant by producing a polymer scaffold composition by electrospinning a polymer solution onto a collector in order to obtain polymer fibers; crosslinking the polymer fibers; and adding a plurality of cells to the polymer scaffold composition, wherein the plurality of cells comprises cartilaginous cells to form a cartilaginous implant.

The present invention relates to a carboxyalkyl chitosan, compositions comprising same, a process for manufacturing same, and various applications thereof, in particular in the field of therapy, rheumatology, ophthalmology, esthetic medicine, plastic surgery, internal surgery, dermatology or cosmetics.

A nasal tissue implant for reconstruction and tissue engineering of nasal tissue in a subject includes a tissue scaffold component comprising a biocompatible polymeric material having a plurality of open pores configured to support cell growth. The tissue scaffold component conforms to a portion of the subject's nasal region and defines at least a portion of the subject's nasal anatomy. A method of making an implantable nasal tissue implant for reconstructing a portion of a nasal anatomy of a human or other animal subject is also provided that includes laser sintering or three-dimensional (3D) printing a biocompatible polymeric material to form a tissue scaffold component comprising a biocompatible polymeric material having a plurality of open pores configured to support cell growth. Again, the tissue scaffold component substantially conforms to a nasal region specific to the human or other animal subject.

Cartilage fibers and implants made therefrom are disclosed, with and without cartilage particles. Methods for making the cartilage fibers and the implants containing them are also disclosed. The implants may be pre-shaped, may be reshapable and, when implanted in a cartilage defect, the implants have good shape retention, little swelling, completely fill the cartilage defect and resist migration from the defect upon irrigation.

Methods of forming a connective tissue-to-bone interface scaffolds (e.g., ligament-to-bone interface scaffolds, tendon-to-bone interface scaffolds, etc.). These scaffolds (grafts) may be formed from in such a way as to provide both a mineralized and demineralized layer in which the entire graft is flexible, compressible and compliant.

The invention relates to a kit of parts, consisting of compositions (C1) and (C2) in separate containers, for use in the treatment or prevention of osteoarthritis in a vertebrate, wherein: (a) composition (C1) is a liquid hydrogel formulation comprising a polymer gellant with chemically cross-linkable groups; (b) composition (C2) is an aqueous auxiliary formulation comprising either one or more dissolved cross-linkers Z having two or more reactive groups that can chemically cross-link the polymer gellant by forming covalent bonds; or comprising one or more dissolved compounds Y, selected from the group consisting of oxidant, oxidase, peroxidase and combinations thereof, that initiate or mediate chemical cross-linking of the polymer gellant; wherein said treatment comprises combining compositions (C1) and (C2) to form a liquid hydrogel composition (C3) and administering said liquid hydrogel composition (C3) to the synovial fluid or to the cavity of a synovial joint of the vertebrate, to form a cross-linked hydrogel (C4) in the synovial joint of the vertebrate; or wherein said treatment comprises in a first step administering one of the compositions (C1) or (C2) to the synovial fluid or to the cavity of a synovial joint of the vertebrate and in a second step administering the other of the compositions (C1) or (C2), to form a liquid hydrogel composition (C3) in the synovial joint of the vertebrate that reacts to a cross-linked hydrogel (C4).

Embodiments of an artificial meniscus are disclosed herein. An artificial meniscus includes at least one circumferential fiber bundle and the at least one non-circumferential fiber bundle embedded in a polymer material. The non-circumferential fiber bundles are fully encapsulated within the polymer material, and the circumferential fiber bundles extend out of anterior and posterior horns of the artificial meniscus to terminate in ends that are configured for fixation to bone. Methods of making and implanting artificial menisci are also disclosed herein. The methods of making include, but are not limited to, stepwise molding, layering, and curing of polymer material around the circumferential and non-circumferential fiber bundles. The methods of implanting include threading ends of the circumferential fiber bundles through first and second bone tunnels, then immobilizing the ends of the circumferential fiber bundles with respect to the bone of the subject.