The present invention relates to anticancer extracellular vesicles, a preparation method therefor, and an anticancer composition comprising same. Immune-tolerized extracellular vesicles containing LDHB and PGC-1α of the present invention provide cancer treatment, suppression of cancer metastasis, and cancer prevention technologies by normalizing cancer cell-specific aerobic glycolysis energy metabolic pathway in which lactate and hydrogen ions, which form a tumor microenvironment favorable for immune evasion, proliferation, metastasis and invasion of cancer cells, are produced, thereby enabling tumors to be effectively removed by means of the immune system of a patient.

A method of obtaining a pancreatic multipotent or unipotent cell including providing a cell of a first type which is not a pancreatic multipotent or unipotent cell; contacting the cell of a first type with an agent capable of remodeling the chromatin and/or DNA of the cell; transiently increasing expression of at least one pancreatic multipotent or unipotent gene regulator in the cell of a first type, to a level at which the at least one pancreatic multipotent or unipotent gene regulator is capable of driving transformation of the cell of a first type into the pancreatic multipotent or unipotent cell; and placing or maintaining the cell in a pancreatic cell culture medium and maintaining intracellular levels of the at least one pancreatic multipotent or unipotent gene regulator for a sufficient period of time to allow a pancreatic multipotent or unipotent cell to be obtained.

This disclosure is directed to mast cells obtained from adipose derived stem cells and sensitized with immunoglobulin-E targeted to a cancer antigen; compositions comprising mast cells obtained from adipose derived stem cells and sensitized with immunoglobulin-E targeted to a cancer antigen; and methods of treating a tumor in a subject, comprising administering to a subject a therapeutically effective amount of mast cells obtained from adipose derived stem cells, wherein the mast cells are autologous to the subject and sensitized with immunoglobulin-E targeted to a cancer antigen.

Provided are a method of preparing a spheroid of stem cells and a composition including the spheroid prepared by the method, the method including: culturing stem cells in a medium supplemented with matrilin-3 protein; and performing 3D cell culture on the cultured stem cells in the medium. The composition disclosed herein has effects of preventing or treating cartilage disease. In detail, the composition may be able to further promote cartilage differentiation of adult stem cells and reduce dedifferentiation and hypertrophy that may occur during cartilage regeneration, thereby providing a more effective cartilage tissue regeneration method.

The present invention relates to an anti-c-Met agonist antibody and use thereof, and more particularly, to an agonist antibody or fragment thereof that specifically binds to a human-derived c-Met protein, to a method for producing the same, to c-Met specific detection method using this, to a composition for preventing or treating cancer comprising the same, to a composition for inducing stem cell differentiation, and a culture medium for stem cells. The method of the present invention can be usefully used for detecting c-Met antibodies, inducing stem cell differentiation using the antibody, and treating or preventing cancer.

The present disclosure relates to a neural cell population, a neural cell-containing preparation, and a method for producing the population and preparation. More particularly, the present invention relates to a neural cell population derived from intraoral mesenchymal cells, wherein a proportion of normal diploid cells is 80% or more, a preparation containing the neural cell population, and a method for producing the population and the preparation.

Here we show that epigenetic control of Neuregulin-1 (NRG1) affects adipose differentiation of stem cells in vitro. Building on this finding, we established a model in which NRG1 is a white adipose tissue (WAT) specific regulator analogous to the role of NRG4 in black adipose tissue (BAT). In this light, NRG1 functions in a paracrine or autocrine manner to regulate formation of new adipocytes from stem populations, both in vitro and in vivo. In neurons, NRG1 has been shown already to play a similar role, promoting neuronal cell differentiation from progenitors in the vertebrate cortex and retina and even promoting neuronal differentiation in vitro. Similarly, in the heart, NRG1 promotes differentiation of cardiomyocytes from their stem cell progenitors both in vivo and in vitro and for this reason has been successfully tested in clinical trials for heart failure. Our model extends these findings to adipose biology and indicates that epigenetic control of NRG1 may constitute an intrinsic mechanism limiting the expansion of WAT depots, potentially elucidating important health implications for the comorbidities of obesity and providing treatment for obesity-related diseases.

Methods are provided for producing a population of hepatocyte-like cells (iHeps) from a population of adipocyte-derived stem cells (ASCs). Aspects of the methods include placing a population of ASCs into a three dimensional culture (e.g., hanging drop suspension culture, high density culture, spinner flask culture, microcarrier culture, etc.), and contacting the cells with a first and second culture medium. Also provided are methods of treating an individual, which include producing a population of iHeps from a population of ASCs, and administering an effective number of iHeps into the individual. Kits for practicing the methods are also described herein.

Methods are provided for producing a population of hepatocyte-like cells (iHeps) from a population of adipocyte-derived stem cells (ASCs). Aspects of the methods include placing a population of ASCs into a three dimensional culture (e.g., hanging drop suspension culture, high density culture, spinner flask culture, microcarrier culture, etc.), and contacting the cells with a first and second culture medium. Also provided are methods of treating an individual, which include producing a population of iHeps from a population of ASCs, and administering an effective number of iHeps into the individual. Kits for practicing the methods are also described herein.

The method for tin vitro or ex vivo amplification of human adipose tissue stem cells includes: —extracting a stromal vascular fraction of a human adipose tissue including endothelial cells of the human adipose tissue vascular network and human adipose tissue stem cells, and an extracellular matrix of the human adipose tissue, the extracellular matrix including endothelial cells of the human adipose tissue vascular network, human adipose tissue stem cells and collagen; —mixing the stromal vascular fraction and the extracellular matrix; and—culturing the mixture obtained in the preceding step, in suspension, in a culture medium.