The present invention is directed towards methods of culturing non-keratinocyte epithelial cells, with the methods comprising culturing non-keratinocyte epithelial cells in the presence of feeder cells and a calcium-containing medium while inhibiting the activity of Rho kinase (ROCK) in the feeder cell, the non-keratinocyte epithelial cells or both during culturing.

Disclosed herein are synthetic leathers, artificial epidermal layers, artificial dermal layers, layered structures, products produced therefrom and methods of producing the same.

The present disclosure provides methods of generating germ layers from stem cells comprising culturing the stem cells in a culture medium having an osmolality less than 340 mOsm/kg. The present disclosure also includes a method to generate different cell lineages from the germ layers as well as to detect them by immunological methods. The present disclosure further provides methods for the generation, isolation, cultivation and propagation of committed progenitor cells and for the production of differentiated cells from the three germ layers. The present disclosure also provides culture media for use in inducing the three germ layers.

An in vitro microfluidic organ-on-chip device is described herein that mimics the structure and at least one function of specific areas of the epithelial system in vivo. In particular, a stem cell-based Lung-on-Chip is described. This in vitro microfluidic system can be used for modeling differentiation of cells on-chip into lung cells, e.g., a lung (Lung-On-Chip), bronchial (Airway-On-Chip; small-Airway-On-Chip), alveolar sac (Alveolar-On-Chip), etc., for use in modeling disease states of derived tissue, i.e. as healthy, pre-disease and diseased tissues. Additionally, stem cells under differentiation protocols for deriving (producing) differentiated lung cells off-chips may be seeded onto microfluidic devices at any desired point during the in vitro differentiation pathway for further differentiation on-chip or placed on-chip before, during or after terminal differentiation. Additionally, these microfluidic stem cell-based Lung-on-Chip allow identification of cells and cellular derived factors driving disease states in addition to drug testing for diseases, infections and for reducing inflammation effecting lung alveolar and/or epithelial regions. Further, fluidic devices are provided seeded with primary alveolar cells for use in providing a functional Type II and Type I cell layer, wherein Type II cells express and secrete surfactants, such as Surfactant B (Surf B; SP-B) and Surfactant C (Surf C; SP-C), which were detectable at the protein level by antibody staining in Type II cells. A number of uses are contemplated for the devices and cells, including but not limited to, for use under inflammatory conditions, in drug development and testing, and for individualized (personalized) medicine. Moreover, an ALI-M was developed for supporting multiple cell types in co-cultures with functional Type II and Type I cells.

The present invention relates to a 3 dimensional mimetic tissue structureAssembloid based on patient-derived multiple cell types to develop next generation organoid technology serving as a novel platform for new drug development and a disease model and a method of manufacturing the same, and more particularly, to a stem cell- or tumor cell-based 3D multicellular mimetic tissue structure manufactured by reconstituting epithelial or tumor cells with various cellular components of a microenvironment such as stromal cells, vascular cells, immune cells or muscle cells based on three-dimensional (3D) bioprinting, and a method of manufacturing the same. As the stem cell- or tumor cell-based 3D multicellular mimetic tissue structure containing the major factors of a tissue microenvironment, such as stromal cells, vascular cells, immune cells and muscle cells, designed according to the present invention is confirmed to mimic physiological and pathological characteristics of tissue in the body better than conventional organoids, normal and tumor assembloids may be used as a new platform for new drug development and a disease model. More specifically, together with 3D bioprinting technology, it is expected that in vitro bladder tissue and bladder tumor tissue are effectively used as a platform to develop precise and personalized therapeutic options for bladder related diseases including bladder cancer.

The present disclosure relates to novel multi-organ-chips establishing the differentiation of induced pluripotent stem cell (iPSC)-derived cells into organ equivalents on microfluidic devices and corresponding methods of generating organ equivalents. The present disclosure also relates to novel bioengineered tissue constructs mimicking organ barriers generated with iPSC-derived endothelial cells and/or organoids bioprinted in, and/or seeded on, a hydrogel. The present disclosure further relates to methods of bio-engineering organ constructs comprising co-culturing iPSC-derived organ precursor cells and iPSC-derived fibroblasts and endothelial cells. The present disclosure specifically provides a microfluidic device comprising: (i) iPSC-derived hepatocyte precursor cells; (ii) iPSC-derived intestinal precursor cells; (iii) iPSC-derived renal tubular precursor cells; and (iv) iPSC-derived neuronal precursor cells; wherein the iPSC-derived precursor cells according to (i), (ii), (iii) and (iv) are differentiated from a single donor iPSC reprogrammed from a single type of somatic cell.

The present invention relates to a medium composition for cell proliferation, skin regeneration, and wrinkle improvement that contains a conditioned medium of pluripotent stem cells (PSCs), neural stem cells (NSCs), and embryonic fibroblasts (FBs) as cells isolated from avian eggs as an active ingredient. Specifically, the conditioned medium of egg cells can fundamentally block contamination due to the use of animal serums, exhibits a proliferation effect of various cells containing human stem cells and skin cells without the possibility of transmission by infectious agents between heterogeneous species due to the use of support cells, and exhibits significant skin regeneration or wrinkle improvement effects, and thus the conditioned medium of egg cells can be usefully used for a medium composition for cell proliferation and a cosmetic composition for skin regeneration or wrinkle improvement.

Disclosed herein are synthetic leathers, artificial epidermal layers, artificial dermal layers, layered structures, products produced therefrom and methods of producing the same.

The present invention pertains to hepatocytes, liver progenitor cells, cholangiocytes, liver sinusoidal endothelial progenitor cells, liver sinusoidal endothelial cells, hepatic stellate progenitor cells, hepatic stellate cells, and liver cellular tissue models, as well as to methods for preparing these cells. The present invention also pertains to a cell fraction comprising liver progenitor cells, liver sinusoidal endothelial progenitor cells, or hepatic stellate progenitor cells. The present invention also pertains to a pharmaceutical composition or kit comprising the above-mentioned cells, a liver cellular tissue model, or a cell fraction. The present invention also pertains to: a method for screening liver disease treatment agents; a method for evaluating the hepatotoxicity of drugs, hepatocytes for infectious disease models, and a method for preparing the same; infectious disease model tissues and a method for preparing the same; as well as a method for screening infectious liver disease treatment agents.

The invention relates to the use of germ cells for obtaining a micro hair follicle and to the use thereof for evaluating the effect of cosmetic, pharmaceutical or dermatological products and also for the prophylactic or therapeutic treatment of a state of reduced pilosity.