The present invention provides a composition comprising fetal cartilage tissue-derived cells and a fetal cartilage tissue-derived extracellular matrix as active ingredients for regenerating a growth plate. The composition for regenerating a growth plate can inhibit bone bridge formation in a growth plate injury region without a scaffold and differentiate to a growth plate cartilage tissue to effectively fill and regenerate the injured region therewith, whereby the regenerated growth plate tissue can recover growth ability. In addition, the composition is compatible with and safe to biological tissues and is characterized by high reproducibility and homogeneity.

The present invention relates to an in vitro method for creating a viable connective tissue and/or osseous tissue obtained by tribological solicitations of a biological culture. It further relates to a viable connective tissue and/or osseous tissue susceptible to be obtained by said method as well as to the use of said method or viable connective tissue and/or osseous tissue to prepare a biological implant.

The present invention relates to a fibrocartilage preparation method and fibrocartilage prepared by the method.

A fetal-origin decellularized nucleus pulposus (NP) allogenic material to regenerate a host's Intervertebral Disc (IVD). The decellularized NP material, obtained from a vertebrate fetus and characterized by comprising high levels of collagen 12 and 14, is used in a pharmacological composition for the treatment of IVD degeneration. The advance is based on the increased ability of the fetal decellularized NP material to stimulate the host constituent cell's to increase the expression of collagen 2 and aggrecan, promoting intrinsic IVD regeneration. A related method includes preparing the pharmaceutical compositions of fetal decellularized material in the form of fragments/microparticles and hydrogel for an injectable mode of administration. The involved material, pharmaceutical compositions and methods may be advantageously used for the prevention and treatment of IVD degeneration and back pain in human and veterinary settings.

The present disclosure aims to provide a manufacturing method of a cell structure. The manufacturing method comprises producing a coated region in which a culturing surface is coated with a temperature-responsive polymer or a temperature-responsive polymer composition, forming a droplet of a cell suspension in the coated region, and performing cell culturing in the droplet. A surface zeta potential of the coated region is 0 mV to 50 mV.

The present invention relates to a method for preparing a porous scaffold for tissue engineering. It is another object of the present invention to provide a porous scaffold obtainable by the method as above described, and its use for tissue engineering, cell culture and cell delivery. The method of the invention comprises the steps consisting of: a) preparing an alkaline aqueous solution comprising an amount of at least one polysaccharide, an amount of a cross-linking agent and an amount of a porogen agent b) transforming the solution into a hydrogel by placing said solution at a temperature from about 4° C. to about 80° C. for a sufficient time to allow the cross-linking of said amount of polysaccharide and c) submerging said hydrogel into an aqueous solution d) washing the porous scaffold obtained at step c).

Described herein are biomaterials, systems, and methods for guiding regeneration of an epiphyseal growth plate or similar interfacial tissue structures. In one aspect, the disclosed technology can include a biologic material that can comprise one or more of a hydrogel carrier for growth factors and MSCs, chondrogenic and immunomodulatory cytokines, microparticles for prolonged and spatially controlled growth factor delivery; and/or porous scaffold providing mechanical support. The implanted material can be applied via various different modalities depending on the nature of the physeal injury. One modality is an injectable hydrogel and another modality is an implantable hydrogel infused scaffold.

It is provided a method of producing high-quality engineered cartilage graft in a human of animal, such as nasal cartilage graft, comprising expanding chondrocytes and/or chondroprogenitors, e.g. autologous human nasoseptal chondrocytes (hNC,) from a donor patient by selecting expanded chondrocytes and/or chondroprogenitors by detecting the expression of at least one surfaceome protein gene or secretome protein gene, wherein the at least one surfaceome protein gene is ADGRG1, NPR3, SLC16A4, TSPAN13, FZD4 and SLC22A23 and the at least one secretome protein gene is ADGRG1, B3GNT7, COLGALT2, IGFBP3, STC2, SAA1, ANGPLT1, COL8A2, INHBB, ADAMTS9, ORM1, COL14A1, DCN, COL21A1, ENOX1, IL7, MXRA5 GAL, TFRC, SERPINA9, LIF, GDF6 and COL5A3.

The present invention relates to a method for fabrication of an extracellular matrix-induced self-assembly and to fabrication of an artificial tissue using same. The method for fabrication of an extracellular matrix-induced self-assembly comprise the steps of: (a) decellularizing and powdering a tissue-derived extracellular matrix (ECM); and (b) adding the decellularized extracellular matrix powder to cells and culturing the cells to form a cell-extracellular matrix powder self-assembly. Accordingly, the self-assembly has characteristics similar to those of extracellular matrix tissues and can be fabricated into three-dimensional artificial tissues 1 cm or greater in size, thus finding advantageous applications as a cell therapy product and an artificial tissue implant.

The present disclosure describes a composition for cartilage defects or deficiencies repair, augmentation or treatment comprising an injectable, in situ polymerizable collagen composition and chondrocytes or stem cells in the collagen composition. The present disclosure also relates to methods for repairing or augmenting or treating cartilage defects or deficiencies using the composition and the preparation method of the composition.