Abstract: A culture medium for culturing chicken embryonic stem (ES) cells is disclosed. The culture medium is used for supporting avian ES cell cultures. The components of the avian ES cell media include cytokines, fibroblast growth factors, insulin-like growth factors and stem cell growth factors and anti-retinoic acid antibody. The culture medium is substantially free of active retinoic acid. A method for culturing avian ES cells and the resulting products are also disclosed.

Abstract: The use of totipotent embryonic stem cells to provide substantially identical cells for embryo cloning techniques is described. The method includes the culture of loose suspensions of inner cell mass cells of bovine animals to retrieve large populations of stem cells. The invention also describes the use of stem cells in various genetic manipulation techniques.

Abstract: The present invention provides a method of treating cancer comprising (a) obtaining a tumor cell line, (b) modifying the tumor cell line to render it capable of producing an increased level of a cytokine relative to the unmodified tumor cell line, and (c) administering the tumor cell line to a mammalian host having at least one tumor that is the same type of tumor as that from which the tumor cell line was obtained, wherein the tumor cell line is allogeneic and is not MHC-matched to the host. The present invention also provides a pancreatic tumor cell line, a method and medium for obtaining such a tumor cell line, and a composition comprised of cells of a purified pancreatic tumor cell line.

Abstract: A patient replica is created from a layered culture medium where solid culture medium is formed so that a discontinuity exists between the layers. An infusion port is provided in registration with the discontinuity so that a fresh unadulterated sample of patient blood can be infused into the discontinuity to form a thin layer of blood between the layers of culture medium. The thin layer obviates the requirement for any anticoagulant allowing blood-borne pathogens to be readily cultured without using broth. Further antibiotics or other drug samples may be placed on the surface of the culture medium above the blood layer so that the antibiotic can diffuse through the culture medium and reveal the sensitivities of the cultured pathogens. Other samples of pathogens or tissues can be placed on the surface of the culture medium so that effects of drugs or growth factors present in the patient blood can be observed thereby allowing the entrapped blood layer to act as a biological replica of the patient.

Abstract: The present invention provides a method for producing an expanded non-transformed cell culture of human liver cells comprising the steps of: (1) preparing partially purified, minced human liver tissue, (2) concentrating the resulting cells and tissue pieces, (3) resuspending the concentrated tissue cells and pieces in a growth medium, (4) culturing the resuspended cells in the growth medium for a time and under conditions to effect sustained cell division, and (5) passaging the cultured human liver cells periodically to expand the culture. The growth medium comprises a combination of a basal medium and ingredients to provide a medium in which the cultured human liver cells are selectively proliferated without being transformed, providing an expanded culture of proliferated, functionally differentiated human liver cells that is substantially free of fibroblast, macrophage and capillary endothelial cells.

Abstract: The subject invention concerns new methods which make it possible, for the first time, to grow functional islets in in vitro cultures. The subject invention also concerns the use of the in vitro grown islet-like structures for implantation into a mammal for in vivo therapy of diabetes. The subject invention further concerns a process using the in vitro grown islet implants for growing an organ in vivo that has the same functional, morphological and histological characteristics as those observed in normal pancreatic tissue. The ability to grow these cells in vitro and organs in vivo opens up important new avenues for research and therapy relating to diabetes.

Abstract: The present invention provides a method for producing an expanded, enriched, non-transformed human cell culture of human pancreatic, thyroid or parathyroid endocrine cells and other types of cells which comprises (1) preparing partially purified, minced tissue that includes a desired type of cells; (2) concentrating the desired cells; (3) resuspending the concentrated cells in a growth medium which selects in favor of the desired cells and in which those cells are proliferated without being transformed and differentiated functions are retained through periodic passaging; (4) culturing the resuspended cells in the growth medium to effect sustained cell division; and (5) passaging the cultured cells periodically to expand the culture.

Abstract: The present invention relates to a substantially pure population of viable bile duct progenitor cells, and methods for isolating such cells. The present invention further concerns certain therapeutic uses for such progenitor cells, and their progeny.

Abstract: Normal mammalian tissue and the culturing process has been developed for the three groups of organ, structural and blood tissue. The cells are grown in vitro under micro-gravity culture conditions and form three dimensional cells aggregates with normal cell function. The microgravity culture conditions may be microgravity or simulated micro-gravity created in a horizontal rotating wall culture vessel. The medium used for culturing the cells, especially a mixture of epithelial and mesenchymal cells contains a mixture of Mem-alpha and Leibovits L15 supplemented with glucose, galactose and fructose.

Abstract: A human pre-oligodendroglial stem cell line, HOP-1, is provided herein. The cell line is useful for methods of treatment of central nervous system disorders, as well as for neuropharmaceutical drug discovery.

Abstract: The present invention relates to a population of blood borne mammalian cells that express a unique profile of surface markers that includes certain markers typical of connective tissue fibroblasts, and are referred to herein as "blood-borne mesenchymal cells." In particular, it relates to the isolation, characterization and uses of such blood-borne mesenchymal cells. The cells of the present invention can be distinguished from peripheral blood leukocytes by their distinct size, morphology, cell surface phenotype and biologic activities, and are likewise distinguishable from connective tissue fibroblasts by other surface phenotypic markers. These cells proliferate in culture, and in vivo, as demonstrated in animal models, are capable of migrating into wound sites from the blood. Therefore, such blood-borne mesenchymal cells may have a wide range of applications, including, but not limited to, the promotion of wound healing, tissue remodeling, and for gene therapy.

Abstract: A method for producing genetically modified neural cells comprises culturing cells derived from embryonic, juvenile, or adult mammalian neural tissue with one or more growth factors that induce multipotent neural stem cells to proliferate and produce multipotent neural stem cell progeny which include more daughter multipotent neural stem cells and undifferentiated progeny that are capable of differentiating into neurons, astrocytes, and oligodendrocytes. The proliferating neural cells can be transfected with exogenous DNA to produce genetically modified neural stem cell progeny. The genetic modification can be for the production of biologically useful proteins such as growth factor products, growth factor receptors, neurotransmitters, neurotransmitter receptors, neuropeptides and neurotransmitter synthesizing genes.

Abstract: A method of culturing non-transformed mammalian respiratory epithelial cells in vitro. The method includes the steps of harvesting the epithelial cells from the respiratory tract of a mammalian donor; suspending the epithelial cells in a fluid culture medium to form a cell suspension; introducing the cell suspension into a first reservoir in communication with an adherence substrate; introducing additional fluid culture medium into a second reservoir separated from the first reservoir by a fluid permeable baffle; incubating the cells under conditions suitable for promoting epithelial cell growth for a period of at least 72 hours; and changing the fluid culture medium within the second reservoir during the incubation period at intervals of approximately 24-72 hours without disturbing the epithelial cells within the first reservoir. Preferably, the epithelial cells are harvested from the nasal mucosa of a human donor using a minimally-invasive brushing technique.