A method for preparing zonal layered chondrocyte sheets, comprising the steps: (a) providing a cartilage sample from a subject; (b) isolating chondrocytes from the cartilage sample and then isolating superficial zone chondrocytes, middle zone chondrocytes and deep zone chondrocytes from the chondrocytes; (c) culturing the deep zone chondrocytes until reaching 100% cell confluence to form a deep zone chondrocyte sheet; (d) seeding the middle zone chondrocytes on the top of the cultured deep zone chondrocyte sheet from the step (c) and culturing the middle zone chondrocytes until reaching 100% cell confluence to form a middle zone chondrocyte sheet; and (e) seeding the superficial zone chondrocytes on the top of the cultured middle zone chondrocyte sheet from the step (d) and culturing the superficial zone chondrocytes until reaching 100% cell confluence to form a superficial zone chondrocyte sheet to obtain the zonal layered chondrocyte sheets.

A pre-sutured allograft construct and method of manufacture for repairing, replacing, reconstructing, or augmenting a hip or shoulder labrum may include a folded tissue portion extending from a first end to a second end and forming top, middle, and bottom folds. A stitched pattern secures the folded tissue portion into a graft roll having an overall length extending from a first adjustable region, through a central region, and through a second adjustable region. A continuous series of whip stitches extends from the first adjustable region, through the central region, and through the second adjustable region. A series of triple circumferential stitches overlays the whip stitches in the first and the second adjustable regions, while a series of circumferential stitches alternates with the whip stitches in the central region. The construct is pre-manufactured as an allograft product, but is adjustable during the surgical procedure within the body. Other embodiments are also disclosed.

Medical devices having engineered mechanically functional cartilage from adult human mesenchymal stem cells and method for making same.

A method for producing a collagen meniscus implant by obtaining a freshly excised non-human meniscus, rinsing it in an aqueous solution, drying the rinsed meniscus, shaping it to approximate in dimension an average-sized human meniscus, extracting non-collagenous material from the shaped meniscus, and sterilizing it, yielding a collagen meniscus implant containing at least 90% by weight of type I collagen, less than 0.5% by weight of glycosaminoglycan, and less than 600 ppm DNA. Also disclosed is a collagen meniscus implant prepared by the above method. Further provided is a biocompatible and bioresorbable porous implant for meniscus repair. The implant includes a three-dimensional network of collagen fibers oriented in a direction approximating the collagen fiber orientation of a human meniscus. The implant has a size and a contour substantially equivalent to a human meniscus, and has a chemical composition similar to the above-described collagen meniscus implant.

Allograft biomaterials, implants made therefrom, methods of making the biomaterial and implants, methods of promoting cartilage, tissue, bone or wound healing in a mammal by administering the biomaterial or implant to the mammal, and kits that include such biomaterials, implants, or components thereof. For example, the allograft may include viable cells, for example, which were native to intervertebral discs and/or umbilical cords that the allograft was derived from.

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 a bacterium.

Cartilage derived tissue compositions, methods of making, and methods of using same. The cartilage derived tissue compositions may comprise porcine nasal septal tissue. The cartilage derived tissue compositions also being processed to retain a beneficial component profile, while reducing cellular and DNA content.

Cell microsheets are formed from a culture of cells. The cell microsheets has a size that can pass through an injection needle with a certain thickness. The cell microsheets can be produced on a surface of a cell cultureware. A stimulus-responsive polymer is immobilized on the surface having small divisions of the cell cultureware. The cell microsheets are suitable for minimally invasive treatment.

A shaped cartilage matrix isolated from a human or animal where the cartilage has been crafted to facilitate disinfection, cleaning, devitalization, recellularization, and/or integration after implantation. Also, a process for repairing a cartilage defect with the cartilage matrix. The matrix is in the form of an osteochondral plug including a cartilage cap ad subchondral bone, wherein one or more gaps, slats, bores, or channels extend through the tidemark at the interface between the cartilage cap and the subchondral bone.

A medical device for repairing injuries to the spinal cord or peripheral nerve has a first flexible substrate supporting first nanoparticles selected from the group consisting of silicon, carbon, gold and titanium, at least partially embedded in a binding layer joined to the first flexible substrate. Each first nanoparticle develops along a preferential direction of development. The nanoparticles are oriented so that, statistically, the preferential direction of development is parallel to a first orientation of growth. Stem cells are at least partially embedded in the binding layer. The first nanoparticles are functionalized so that stem cell differentiation along the first nanoparticles is guided in the first orientation of growth. The first flexible substrate is suitable to assume a distended configuration and a wrapped configuration in which it is wrapped around the spinal cord or peripheral nerve whereby the first orientation of growth is statistically parallel to the neuronal direction of extension of neurons of the spinal cord or peripheral nerve.