The present invention relates to a composition for inducing dedifferentiation form somatic cells to induced pluripotent stem cells (iPSs) and method of inducing dedifferentiation using same, wherein the composition for inducing dedifferentiation and the method of inducing dedifferentiation increases the efficiency of dedifferentiation from somatic cells to iPSs by stimulating CXC chemokine receptor 2 (CXCR2), which is a receptor on human somatic ells, and thus may be effectively used for inducing the dedifferentiation to iPSs.

The presently disclosed subject matter provides a microfluidic device that can simulate capillary blood flow on a fetal side of the device and pooled blood on a maternal side of the device (i.e., intervillous space). The microfluidic device can reconstitute the maternal-fetal interface, can expand the capabilities of cell culture models, and can provide an alternative to current maternal-fetal transfer models.

The present invention aim at providing a novel animal cell growth promoter. Specifically, a culture supernatant of an embryonic membrane derived from an avian or reptilian fertilized egg is use as an animal cell growth promoter. For example, by adding, to an animal cell culture medium, an animal cell growth promoter comprising, as an active ingredient, a culture supernatant of an embryonic membrane derived from an avian or reptilian fertilized egg, the animal cell growth can be promoted.

The present invention relates to a biologically active placenta-derived liquid human substrate (hpS) comprising extracellular matrix (ECM) proteins, cytokines and growth factors and use thereof. The present invention also provides methods of producing a composition comprising biologically active placenta-derived liquid human substrate (hpS).

Provided herein is a placental product comprising an immunocompatible amniotic membrane. Such placental products can be cryopreserved and contain viable therapeutic cells after thawing. The placental product of the present invention is useful in treating a patient with a tissue injury (e.g. wound or burn) by applying the placental product to the injury. Similar application is useful with ligament and tendon repair and for engraftment procedures such as bone engraftment.

The present invention relates to stem cells derived from a multi-layered cellular structure or blastocyst structure, compositions comprising the same, and methods for obtaining the same.

Methods of reducing T cell activation including co-culturing with T cells, term amniotic fluid mesenchymal stem cells (TAF-MSCs) isolated from term human amniotic fluid. Other aspects relate to methods of inhibiting macrophage polarization toward the M1 pro-inflammatory phenotype including co-culturing with macrophages TAF-MSCs isolated from term human amniotic fluid. Other aspects relate to methods of inhibiting cytokine secretion from activated Peripheral Blood Mononuclear Cell (PBMC) including co-culturing with the PBMC tissue-typed TAF-MSCs isolated from human amniotic fluid. Other aspects relate to methods of differentiating TAF-MSC including: obtaining TAF-MSC cells from term amniotic fluid, plating the TAF-MSC cells in limiting dilution to obtain expanded colonies from single cells, and transferring the cells to a differentiation media that contains one or more factor to differentiate the TAF-MSC cells.

Provided herein are methods of using tissue culture plastic-adherent placental adherent cells, e.g. placental stem cells, referred to herein as placental adherent cells, to treat lymphedema and lymphedema-related disorders.

Disclosed is a cell-derived extracellular matrix (ECM) derived in vitro from cells isolated from amniotic fluid, and methods of use for the isolation, maintenance, and proliferation of adherent cells including stem cells, as well as for the differentiation of stem cells.

Various embodiments of the invention provide methods of treating diabetes and other glucose regulation disorders. In one embodiment, the method comprises removing L-cells from a donor, obtaining stem cells from a patient, and culturing the L-cells in the presence of the stem cells under conditions such that the stem cells differentiate into stem cell-derived L-cells (SCDLC). An amount of the SCDLC is introduced into the patient sufficient to cause a lowering of the patient's blood glucose level after ingestion of food. In another embodiment, the method comprises removing K-cells from a donor, obtaining stem cells from a patient, and culturing the K-cells in the presence of the stem cells under conditions such that the stem cells differentiate into stem cell-derived K-cells (SCDKC). An amount of the SCDKC is introduced into the patient sufficient to cause a lowering of the patient's blood glucose level after ingestion of food.