An object of the invention is to provide a cartilage regenerative material that suppresses infiltration of fibrous soft tissue and brings about satisfactory cartilage regeneration, and a method for producing the cartilage regenerative material. Provided is a cartilage regenerative material including a porous body of a biocompatible polymer and a biocompatible polymer film, in which the porous body contains chondrocytes and cartilage matrix, and the cartilage matrix exists in a region of 10% or more of a region extending from the surface of the transplant face of the porous body to a depth of 150 μm along the thickness.

The disclosure provides a chondrocyte cell sheet comprising one or more layers of confluent cells comprising chondrocytes and chondroprogenitor cells. Methods of generating cartilage tissue in a subject are also provided. The disclosure also provides a method for producing chondrocyte cell sheets comprising culturing chondrocytes and chondroprogenitor cells in culture solution on a temperature-responsive polymer which has been coated onto a substrate surface of a cell culture support, wherein the temperature-responsive polymer has a lower critical solution temperature in water of 0-80° C.; adjusting the temperature of the culture solution to below the lower critical solution temperature, whereby the substrate surface is made hydrophilic and adhesion of the cell sheet to the surface is weakened; and detaching the cell sheet from the culture support.

Provided herein are meniscus implant compositions, as well as method for making and using the same. The subject meniscus implants find use in repairing and/or replacing damaged or diseased meniscal tissue in a mammalian subject.

The present invention relates to a three-dimensional multiphasic synthetic tissue scaffold comprising first, second and third compartments, wherein: each said compartment comprises distinct microstructural, and/or chemical, and/or mechanical properties, and is connected with at least one other compartment of the scaffold via a continuous interface; the tissue scaffold is porous; and the external morphology of the tissue scaffold mimics that of a mammalian joint or a component thereof. The invention further relates to a method for producing the three dimensional multiphasic synthetic tissue scaffold using a polymeric material, the method comprising using a three-dimensional (3D) bioprinter to print the tissue scaffold by continuously deposit the polymeric material onto a platform until the tissue scaffold is produced in its entirety.

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.

Methods and compositions for the biological repair of cartilage using a hybrid construct combining both an inert structure and living core are described. The inert structure is intended to act not only as a delivery system to feed and grow a living core component, but also as an inducer of cell differentiation. The inert structure comprises concentric internal and external and inflatable/expandable balloon-like bio-polymers. The living core comprises the cell-matrix construct comprised of HDFs, for example, seeded in a scaffold. The method comprises surgically removing a damaged cartilage from a patient and inserting the hybrid construct into the cavity generated after the foregoing surgical intervention. The balloons of the inert structure are successively inflated within the target area, such as a joint, for example. Also disclosed herein are methods for growing and differentiating human fibroblasts into chondrocyte-like cells via mechanical strain.

The present invention provides a cartilage regenerating composition including a fetal cartilage tissue-derived cell and an extracellular matrix derived from a fetal cartilage tissue, and a preparing method thereof. According to the present invention, the cartilage-regenerating composition may produce a three-dimensional tissue of a size suitable for use as a cartilage without a scaffold, may be easily transplantable regardless of the size and shape of the cartilage defect at the site of administration since it can be administered in the form of a gel, but has high application and adhesion, may exhibit a high binding ability to the host tissue, and may have a phenotype of mature cartilage tissue, thereby exhibiting an excellent cartilage regeneration effect.

Provided herein are compositions comprising collagen, dialdehyde starch, and at least one population of cells. Also, provided herein are methods of bioprinting and methods of producing cell-laden, three-dimensional scaffolds, comprising the compositions described herein.

A cryopreserved cartilage product is disclosed. The cryopreserved cartilage product can include a partially digested cryopreserved natural cartilage collagen matrix isolated from a subject. The collagen matrix can include viable cells embedded within the collagen matrix that are native to the collagen matrix and that were embedded in the collagen matrix when the collagen matrix was isolated from the subject, at least 70% of the embedded cells native to the collagen matrix can be viable in the cryopreserved cartilage product, and the partially digested collagen matrix can retain interaction between the collagen matrix and the native cells.

Collagen compositions, methods for preparing those collagen compositions, and 3D constructs formed from those collagen compositions are provided. In particular, methods of isolating collagen that exhibits an enhanced rate of gelling, such collagen compositions, and 3D constructs formed from such collagen compositions are provided.