The present invention relates to a new method for treating human or animal tissue such as cartilage, particularly damaged tissue. More specifically, the invention relates to a method to obtain material for treating the damaged tissue, for example any cartilage damage, in particular as a result of traumatic or degenerative cartilage damage.

The subject invention is directed to a composition comprising primed connective tissue cells and a pharmaceutically acceptable carrier thereof.

The present invention relates to canine amniotic membrane-derived multipotent stem cells (cAM-MSCs) and preparation method thereof. More particularly, the present invention relates to canine amniotic membrane-derived multipotent stem cells, which show negative immunological properties on human markers CD3, CD11c, CD28, CD34, CD38, CD41a, CD45, and CD62L and positive immunological properties on human markers CD90 and CD105, and have the ability to be maintained in an undifferentiated state for 20 passages or more and the ability to be differentiated into fat, bones, nerves, cartilage, etc.

The invention provides a method of producing a connective tissue graft suitable for correcting a connective tissue defect, comprising determining the size and shape of a tissue defect, obtaining a fat tissue from a patient modelled to fit the size and shape of the tissue defect, contacting the fat tissue with one or more connective tissue specific growth or differentiation factors; and kits for such a method.

A fresh tissue allograft having at least one tissue portion maintained above a predetermined temperature to reduce the rate of cell death. A storage media having at least one free-radical scavenger is applied to the allograft to further slow the rate of cell death.

The invention provides a quiescent stem cell having the capacity to differentiate into ectoderm, mesoderm and endoderm, and which does not express cell surface markers including MHC class I, MHC class II, CD44, CD45, CD13, CD34, CD49c, CD73, CD105 and CD90. The invention further provides a proliferative stem cell, which expresses genes including Oct-4, Nanog, Sox2, GDF3, P16INK4, BMI, Notch, HDAC4, TERT, Rex-1 and TWIST but does not express cell surface markers including MHC class I, MHC class II, CD44, CD45, CD13, CD34, CD49c, CD73, CD105 and CD90. The cells of the invention can be isolated from adult mammals, have embryonic cell characteristics, and can form embryoid bodies. Methods for obtaining the stem cells, as well as methods of treating diseases and the differentiated stem cells, are also provided.

A method for the in vitro detection of cartilage tissue and/or for the in vitro determination of the purity of cartilage tissue includes: a) treating a tissue sample with a protease and b) testing the protease-treated tissue sample for the presence of protease-resistant fragments of type II collagen and/or type I collagen. Methods can be carried out for preparing a cartilage cell culture, and for preparing a cartilage cell-loaded implant. Protease-resistant fragments of type II collagen and/or type I collagen can be used for the in vitro detection of cartilage tissue and/or for the in vitro determination of the purity of cartilage tissue. A kit can be used for carrying out the methods.

The present disclosure relates to methods and systems of tissue engineering, and, more particularly, to optimization of tissue regeneration using cell cycle synchronization of stem cells.

Various cells, stem cells, and stem cell components, including associated methods of generating and using such cells are provided. In one aspect, for example, an isolated cell that is capable of self-renewal and culture expansion and is obtained from a subepithelial layer of a mammalian umbilical cord tissue. Such an isolated cell expresses at least three cell markers selected from CD29, CD73, CD90, CD166, SSEA4, CD9, CD44, CD146, or CD105, and does not express at least three cell markers selected from CD45, CD34, CD14, CD79, CD106, CD86, CD80, CD19, CD117, Stro-1, or HLA-DR.

The application provides the use of CD73, CD105, CD44 and/or CD10 for determining osteogenic potential of in vitro differentiated cells. The application further provides a method for determining osteogenic potential of in vitro differentiated cells comprising measuring the quantity of the in vitro differentiated cells expressing CD73, CD105, CD10 and/or CD44, and/or measuring the quantity of CD73, CD105 and/or CD44 expressed by the in vitro differentiated cells. The invention also provides a method for selecting a subject for preparing in vitro differentiated cells of chondro-osteoblastic lineage comprising recovering MSC from a biological sample of a subject; obtaining in vitro differentiated cells from the MSC; determining the osteogenic potential of the in vitro differentiated cells by a method as disclosed herein; and selecting the subject for preparing in vitro differentiated cells of chondro-osteoblastic lineage if the in vitro differentiated cells have clinically useful osteogenic potential.