The present invention pertains to methods for manufacturing high titer antibody products. In particular, the invention pertains, in part, to improved serum-free animal cell culture medium, which can used for the production of a protein of interest. Additionally, the present invention further pertains to chromatographic procedures employed to successfully isolate the antibody product subject of the present disclosure.

An object of the present invention is to provide an endodermal cell population for obtaining optimal somatic cells as cell therapy preparations. The endodermal cell population of the present invention has a reduced content proportion of undifferentiated cells in the cell population and contains endodermal cells differentiable into optimal somatic cells as cell therapy preparations. Further, a somatic cell derived from the endodermal cell population of the present invention has excellent therapeutic effects as a cell therapy preparation.

The application describes a method for producing a population of cardiac stromal cells from pluripotent stem cells. Specifically, the method relates to (i) inducing epithelial-mesenchymal transition of pluripotent stem cell derived epicardial cells and (ii) amplifying the number of cardiac stromal cells in serum-free conditions. These cardiac stromal cells can be mass produced according to the described method and said cells maintain the expression of CD90, CD73 and CD44 in at least 80% of the cardiac stromal cells. Furthermore, the application relates to a population of cardiac stromal cells, which are pluripotent stem cells derived and wherein at least 80% of the cardiac stromal cells express CD90, CD73 and CD44. Said cardiac stromal form the basis for several in vitro and in vivo applications such as the production of engineered organ tissue and the support of, for example, heart repair. Also, a serum- free culture medium for the amplification of cardiac stromal cells is provided herein.

A cell preservation medium, a cell recovery medium and a cell culture medium, and methods which employ the media, are provided.

The present invention relates to a culture media system that useful for the isolation and epigenetically stable propagation of normal stem cells in culture which are derived from columnar epithelial tissues and cancer stem cells from epithelial cancers. In certain embodiments, the culture system is a feeder-free system.

Provided are a composition for inducing cell transdifferentiation and use thereof in inducing the transdifferentiation of non-neuronal cells into neurons. The composition comprises a myosin inhibitor, and an isoxazole compound and/or a derivative thereof. Further provided is a method for inducing the transdifferentiation of non-neuronal cells into neurons, comprising: culturing the non-neuronal cells in an induction culture solution comprising a myosin inhibitor, and then culturing them in a mature culture solution comprising a myosin inhibitor, and an isoxazole compound and/or a derivative thereof, so as to obtain mature neurons. Also provided is a method for transdifferentiating non-neuronal cells within a subject into neurons, comprising administering to the subject an effective amount of a myosin inhibitor, and an isoxazole compound and/or a derivative thereof.

Disclosed herein, are methods for identifying a drug candidate for treating cancer metastasis. The method comprising culturing an embedded organoid/natural killer (NK) cell co-culture with a drug candidate; and measuring one or more metastatic properties of the embedded organoid or tumor-killing potential or tumor-promoting potential of the NK cells in the co-culture.

Described herein are methods and compositions related to generation of induced pluripotent stem cells (iPSCs). Improved techniques for establishing highly efficient, reproducible reprogramming using non-integrating episomal plasmid vectors. Using the described reprogramming protocol, one is able to consistently reprogram non-T cells with close to 100% success from non-T cell or non-B cell sources. Further advantages include use of a defined reprogramming media E7 and using defined clinically compatible substrate recombinant human L-521. Generation of iPSCs from these blood cell sources allows for recapitulation of the entire genomic repertoire, preservation of genomic fidelity and enhanced genomic stability.

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.

The present invention relates to a method of isolating a mesenchymal stem cell population from the amniotic membrane of the umbilical cord, the method comprising cultivating umbilical cord tissue in a culture medium comprising DMEM (Dulbecco's modified eagle medium), F12 (Ham's F12 Medium), M171 (Medium 171) and FBS (Fetal Bovine Serum). The invention also relates to a mesenchymal stem population isolated from the amniotic membrane of the umbilical cord, wherein at least about 90% or more cells of the stem cell population express each of the following markers: CD73, CD90 and CD105 and lack expression of the following markers: CD34, CD45 and HLA-DR. The invention also relates to a pharmaceutical composition of this mesenchymal stem population.