The present invention relates to methods for encapsulating pancreatic progenitors in a biocompatible semi-permeable encapsulating device. The present invention also relates to production of human insulin in a mammal in response to glucose stimulation.

The invention relates to improved culture methods for expanding epithelial stem cells and obtaining organoids, to culture media involved in said methods, and to uses of said organoids.

A problem of this invention it to provide a method for differentiate a primordial germ cell into a functional GV stage oocyte by in vitro culture. This invention relates to a method for differentiating a primordial germ cell into a functional GV stage oocyte by in vitro culture, comprising: (a) a step of producing a secondary follicle by culturing the primordial germ cell and supporting cells adjacent to the primordial germ cells under conditions that eliminate the effects of estrogen or a factor having a similar function to estrogen; (b) a step of partially dissociating cells between a granulosa cell layer and a thecal cell layer, wherein an oocyte, the granulosa cell layer, and the thecal cell layer constitute the produced secondary follicle; and (c) a step of differentiating the oocyte into a functional GV stage oocyte by culturing the oocyte, the granulosa cell layer, and the thecal cell layer that constitute the secondary follicle in a medium containing a high-molecular-weight compound.

Disclosed is a method for differentiating induced pluripotent stem cells (iPSCs) into chondrocytes and integrating them into a matrix/scaffold to provide a cartilage implant. The method comprises the steps of seeding a surface of a substrate with iPSCs. The surface is coated with nanoparticles in a particle density of at least 500 particles/μm2, and parts of the surface in between said nanoparticles are coated with a coating agent. Growth differentiation factor 5 (GDF5) molecules are attached to the nanoparticles. The method further comprises the steps of adding a first differentiation medium to the seeded iPSCs and allowing the seeded iPSCs to differentiate at least into chondrocyte progenitor cells on the surface in the presence of the first differentiation medium. The obtained differentiated cells are integrated into a matrix/scaffold.

Provided herein are methods of producing β cells and precursors thereof utilizing a Wnt signaling inhibitor or PKC activator, or both. Also provided herein are in vitro cultures comprising said cells, methods of treating a subject with a disease characterized by high blood sugar levels over a prolonged period of time by administering said cells, and devices for encapsulating said cells.

Provided herein are methods of producing β cells and precursors thereof utilizing a Wnt signaling inhibitor or PKC activator, or both. Also provided herein are in vitro cultures comprising said cells, methods of treating a subject with a disease characterized by high blood sugar levels over a prolonged period of time by administering said cells, and devices for encapsulating said cells.

The present invention is drawn, in part, to biocompatible compositions comprising a biocompatible polymer matrix and conditioned cell medium comprising i) a cell culture medium and ii) one or more agents synthesized by and secreted from one or more cells cultured in the cell culture medium, as well as therapeutic uses thereof, particularly in modulating bone and/or gum tissue growth.

The present invention provides methods to promote the differentiation of pluripotent stem cells. In particular, the present invention provides methods to produce a population of cells, wherein greater than 10% of the cells in the population express markers characteristic of single hormonal pancreatic beta cells.

The present invention provides methods to promote the differentiation of pluripotent stem cells. In particular, the present invention provides methods to produce a population of cells, wherein greater than 10% of the cells in the population express markers characteristic of single hormonal pancreatic beta cells.

The present invention describes in vitro methods for producing a cellular composition with in vivo bone forming potential.