Various embodiments of the invention provide methods of treating diabetes and other glucose regulation disorders. In one embodiment, the method comprises removing L-cells from a donor, obtaining stem cells from a patient, and culturing the L-cells in the presence of the stem cells under conditions such that the stem cells differentiate into stem cell-derived L-cells (SCDLC). An amount of the SCDLC is introduced into the patient sufficient to cause a lowering of the patient's blood glucose level after ingestion of food. In another embodiment, the method comprises removing K-cells from a donor, obtaining stem cells from a patient, and culturing the K-cells in the presence of the stem cells under conditions such that the stem cells differentiate into stem cell-derived K-cells (SCDKC). An amount of the SCDKC is introduced into the patient sufficient to cause a lowering of the patient's blood glucose level after ingestion of food.

Provided herein are a method of promoting osteogenic differentiation efficiency of a stem cell or of inducing chondrogenic differentiation of a stem cell, comprising treating the stem cell with a culture solution of chicken bone marrow-derived osteochondroprogenitor cells; a method of preventing or treating cartilage damage or a cartilage defect disease comprising administering to a subject in need thereof a composition comprising a differentiation-induced stem cell or differentiated chondrocyte made by said method as an active ingredient; and a method of preventing or treating a bone disease, cartilage damage, or a cartilage defect disease comprising administering to a subject in need thereof, a composition comprising a culture solution or culture concentrate of chicken bone marrow-derived osteochondroprogenitor cells as an active ingredient.

Provided is a composition capable of promoting osteogenic differentiation of stem cells, comprising, as active ingredients, a bone and cartilage progenitor cell culture solution and a multilayer graphene film, which promotes the differentiation of stem cells into specific cells, and thus is expected to be variously applicable in the in vivo/in vitro stem cell application fields.

The present disclosure relates to cellular compositions that are modified to introduce a nucleic acid or vector expressing the same. Such compositions may be used to deliver nucleic acid to a target cell and treat disease such as cancer.

The present invention provides processes for producing a bioengineered lung (BEL) from an acellular lung matrix that has been treated with growth hormones, seeded with primary lung cells, and cultured in a bioreactor. Also provided are BELs and methods of transplanting the BEL into a subject in need of a lung transplant, and methods for using BELs for the study of the lung microbiome and its role in lung development and remodeling.

Systems and methods for the dynamic co-culturing of two cell populations are provided. The system includes a barrier configured to physically separate a stimulator cell population from a responder cell population disposed within a container. The barrier is permeable to the secreted factors of at least one of the cell populations. The responder cell population can thereby be altered by exposure to the secreted factors to produce a population of reprogrammed cells that includes biomolecules (e.g., nucleic acids) originating from the stimulator cell population and/or that exhibits one or more additional or modified functional activities than a parental population of the reprogrammed cells.

The invention relates to an ex vivo generated population of tissue-specific anti-inflammatory macrophages and methods of making and using such macrophages.

Provided herein are methods of modulating monocyte phenotypes using isolated mesenchymal stem cell (MSC) exosomes. Monocytes treated with MSC exosomes can be used to treat fibrotic disease and autoimmune diseases.

The present invention relates to three-dimensional (3D) tissue constructs and methods of using such 3D tissue constructs to screen for neurotoxic agents. In particular, provided herein are methods of producing and using complex, highly uniform human tissue models comprising physiologically relevant human cells, where the tissue models have the degree of sample uniformity and reproducibility required for use in quantitative high-throughput screening applications.

Methods for culturing cells, compositions comprising the cell culture product, and applications for the compositions are described. Methods include culturing cells with a media that includes a catalyst compound, which can include a stilbene or a nicotinamide compound, so as to control the secretome of the cells. Compositions that include the cell culture product include the cell secretome or components thereof in conjunction with at least one catalyst compound. Products can be utilized as a cell culture media or can be utilized in therapeutic applications.