Abstract: 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.

Abstract: Systems and methods for automated cell processing of biological samples, such as cells for use in cell therapy and regenerative medicine. Systems for automated processing of batches derived from biological samples comprise: a closed and sterile enclosure; a plurality of reagent containers; at least one reagent dispenser; a quality control module for analyzing at least one characteristic of a batch; a harvesting module; a robotic module; and a control unit (CU) communicatively coupled to the at least one reagent dispenser, the quality control module, the harvesting module and the robotic module for controlling the automatic processing of batches. The automatic processing may be executable without handling by a human operator. The system may be configured to automatically process the plurality of batches without cross-contamination between batches, e.g., under GMP conditions.

Abstract: The present invention provides methods and compositions useful in the regeneration of damaged, lost and/or degenerated tissue in humans and animals. In certain embodiments, the present invention provides an acellular bioabsorbable tissue regeneration matrix, methods of making such a matrix, and methods of using such a matrix for the regeneration of damaged, lost and/or degenerated tissue. In certain embodiments, methods and compositions of the present invention are useful in the treatment of damaged, lost and/or degenerated nerve tissue.

Abstract: The present invention is drawn to a 3-dimensional cell-produced scaffold construct comprising cells and the extracellular matrix that has been produced and arranged by these cells.

Abstract: An in vitro human neural multipotent, unipotent, or somatic cell possessing all of the following characteristics: is derived from the reprogramming of a somatic cell, a progenitor cell or a stem cell that exhibits at least a transient increase in intracellular levels of at least one reprogramming agent; is not differentiated from a pluripotent cell; expresses one or more markers of a multipotent, unipotent or somatic cell not characteristic of a neural stem cell, neural precursor cell, neural progenitor cell, neuroblast, or neuron; is not a cancerous cell; is stable and not artificially maintained by forced gene expression and may be maintained in standard neural stem cell media or neural media; and does not exhibit uncontrolled growth, teratoma formation, and tumor formation in vivo; wherein the cell comprises at least one polypeptide or an expression vector encoding at least one polypeptide selected from the group consisting of: Musashi1 (Msi1); Ngn2; Msi1 and Ngn2; Msi1 and methyl-CpG binding domain protei

Abstract: A method of obtaining a neural multipotent, unipotent or somatic cell, comprising: i) providing a cell of a first type which is not a neural multipotent, unipotent or somatic cell; ii) introducing into the cell of a first type an agent capable of remodeling the chromatin and/or DNA of the cell, wherein the agent capable of remodeling the chromatin and/or DNA is a histone acetylator, an inhibitor of histone deacetylation, a DNA demethylator, and/or a chemical inhibitor of DNA methylation; iii) increasing directly or indirectly the endogenous expression of at least one neural multipotent or unipotent gene regulator in the cell of a first type, to a level at which the gene regulator is capable of driving transformation of the cell of a first type into the neural multipotent, unipotent or somatic cell, wherein the gene regulator is Msi1, Ngn2, Sox2, Ascl1, Zic1 or a combination thereof; and iv) placing or maintaining the cell in a neural cell culture medium and maintaining intracellular levels of the reprogrammin

Abstract: Described herein are methods for cell dedifferentiation, transformation and eukaryotic cell reprogramming. Also described are cells, cell lines, and tissues that can be transplanted in a patient after steps of in vitro dedifferentiation and in vitro reprogramming. In particular embodiments the cells are Stem-Like Cells (SLCs), including Neural Stem-Like Cells (NSLCs). Also described are methods for generating these cells from human somatic cells and other types of cells. Also provided are compositions and methods of using of the cells so generated in human therapy and in other areas.

Abstract: Described herein are methods for cell dedifferentiation, transformation and eukaryotic cell reprogramming. Also descried are cells, cell lines, and tissues that can be transplanted in a patient after steps of in vitro dedifferentiation and in vitro reprogramming. In particular embodiments the cells are Stem-Like Cells (SLCs), including Neural Stem-Like Cells (NSLCs). Also described are methods for generating these cells from human somatic cells and other types of cells. Also provided are compositions and methods of using of the cells so generated in human therapy and in other areas.