The current invention concerns a composition for treating trauma in a subject, where the composition includes isolated mesenchymal stem cells (MSCs), wherein the MSCs are tenogenic-induced and/or chondrogenic-induced, and where the trauma is tendon trauma, traumas of the ligaments, or trauma of cartilage.

The present invention relates to providing artificial tendon or ligament tissue having sufficient strength. More specifically, artificial tendon or ligament tissue having sufficient strength is provided by embedding collagen-secreting cells in a gel having strength capable of resisting a tensile load and by culturing the cells while applying a tensile load to the gel to produce artificial tendon or ligament tissue. Cells that steadily express the Mkx gene can be used as the collagen-secreting cells. A fibrin gel containing aprotinin can be used as the gel.

A method is disclosed for coating and patterning hydrogels in order to modify surface properties. The method exploits the water content of the hydrogel and the hydrophobicity of the reaction solvent to create a thin oxide adhesion layer on the hydrogel surface. This oxide adhesion layer enables rapid transformation of the hydrophilic, cell non-adhesive hydrogel into either a highly hydrophobic or a cell-adhesive hydrogel by reaction with an alkylphosphonic acid or an α,ω-diphosphonoalkane, respectively. Also disclosed are coated, patterned hydrogels and constructs comprising the coated, patterned hydrogels.

Culturing a cartilage or bone progenitor cell in a medium containing a TGF-β signal inhibitor and FGF is effective for expansion culture of a cartilage or bone progenitor cell, and inducing differentiation of a cartilage or bone progenitor cell obtained by such a method is effective for producing a chondrocyte or osteocyte.

In some embodiments, the invention provides tissue-on-a-chip and organ-on-a-chip devices with integrated, on-board photonic integrated circuit optical sensors that allow real-time detection of analytes released from cells disposed on either side of a porous, ultrathin membrane within the device. The invention further provides modular devices for studying cells and interactions between and among cell types. The devices and methods using them are useful for, among other thing, modeling the biological and physiological interactions of cells of different tissue types, allowing high-throughput screening of drug candidates, and informing safety and efficacy in a virtual clinical trial.

Microvesicles produced by stem cells grown on a silk scaffold for enhancing stem cell self-renewal/proliferation and promoting tenogenesis in damaged tendons, and their use in tendon wound repair and tendinopathy treatment. Also provided are compositions containing the microvesicles and devices for obtaining them.

The present disclosure relates to a novel musculoskeletal stem cell (MSSC) differentiated from an ESC (embryonic stem cell) or an iPSC (induced pluripotent stem cell). The musculoskeletal stem cell of the present disclosure can be easily induced from a human embryonic stem cell or a human-derived pluripotent stem cell and can be effectively differentiated not only into bone but also into cartilage, tendon and muscle. Accordingly, it can be usefully used for prevention or treatment of various musculoskeletal diseases.

A method for obtaining a fraction of a fetal cell culture supernatant, including the steps of obtaining a cell-containing sample of tissue (such as cartilage) or (cord-)blood or bone marrow from a non-human mammalian fetus, culturing the sample in a liquid cell culture medium, thereby obtaining a cell culture with a liquid supernatant, and isolating a fraction from the supernatant. Furthermore, a fraction obtainable by this method is provided. A pharmaceutical composition including this fraction is also provided, preferably for use in therapy, such as for use in a prevention or treatment of osteoarthritis, arthritis, tendinitis, tendinopathy, cartilage injury, tendon injury, rheumatoid arthritis, discospondylitis, meniscus injury, desmitis, desmopathy, intervertebral disc injuries, degenerative disease of intervertebral discs, reperfusion injury, wounds or inflammatory disease.

The present invention relates to providing artificial tendon or ligament tissue having sufficient strength. More specifically, artificial tendon or ligament tissue having sufficient strength is provided by embedding collagen-secreting cells in a gel having strength capable of resisting a tensile load and by culturing the cells while applying a tensile load to the gel to produce artificial tendon or ligament tissue. Cells that steadily express the Mkx gene can be used as the collagen-secreting cells. A fibrin gel containing aprotinin can be used as the gel.

A method is disclosed for coating and patterning hydrogels in order to modify surface properties. The method exploits the water content of the hydrogel and the hydrophobicity of the reaction solvent to create a thin oxide adhesion layer on the hydrogel surface. This oxide adhesion layer enables rapid transformation of the hydrophilic, cell non-adhesive hydrogel into either a highly hydrophobic or a cell-adhesive hydrogel by reaction with an alkylphosphonic acid or an α,ω-diphosphonoalkane, respectively. Also disclosed are coated, patterned hydrogels and constructs comprising the coated, patterned hydrogels.