The systems and methods of the present disclosure can be used to generate systems and models that are physiologically relevant to the human and animal system. These physiological conditions can be designed to mimic the actual human condition for cell differentiation and proliferation. The system and methods of this present disclosure allow the formation of an appropriate biomaterial to mimic that which exists in a human or animal scaffold. Utilizing 3D printing technology, a hydrogel scaffold can be printed at various resolution very close to human physiological geometry. Additionally, the architecture can be optimized for the selected application and appropriate cells can be seeded on the scaffold prior to testing.

Disclosed herein are methods for introducing functional mitochondria into liver cells in living animals (e.g., mammals). The disclosed compositions and methods can be used to treat clinical conditions characterized by genetic or acquired mitochondrial defects and the resulting dysfunctions and diseases therefrom.

Disclosed herein are cell cultures comprising dorsal and/or ventral PDX1-positive foregut endoderm cells and methods of producing the same. Also disclosed herein are cell populations comprising substantially purified dorsal and/or ventral PDX1-positive foregut endoderm cells as well as methods for enriching, isolating and purifying dorsal and/or ventral PDX1-positive foregut endoderm cells from other cell types. Methods of identifying differentiation factors capable of promoting the differentiation of dorsal and/or ventral PDX1-positive foregut endoderm cells, are also disclosed.

Hybrid suspension cultures supplementing soluble extracellular matrix (ECM) for growth of organoids is disclosed. Viable lung organoid from epithelial, endothelial, and fibroblast human stable cell lines in suspension culture are also disclosed.

Described are engineered cells that include genetic alterations leading to up- or down-regulation of certain genes in the cells for improved production of a recombinant protein, especially one that is not easily expressed at high levels in unaltered cell lines. Also provided are methods of preparing and using such cells.

Composites based on a polymer and a mixture of proteins derived from a MaSp (major ampullate spidroin) protein are provides. Further, methods for preparation of same, and method of use of the composites are provided.

The present invention relates in part to methods for producing tissue-specific cells from patient samples, and to tissue-specific cells produced using these methods. Methods for reprogramming cells using RNA are disclosed. Therapeutics comprising cells produced using these methods are also disclosed.

The invention is directed to methods for culturing cells so that the cells are induced to differentiate into cells that express a hepatic stellate phenotype. The invention is also directed to cells produced by the methods of the invention. The cells are useful, among other applications, for treatment of liver deficiencies, liver metabolism studies, and liver toxicity studies, fibrogenic studies, or to support hepatocyte function in co-culture setting.

Disclosed herein is a multicellular lay-up process. The process comprises the steps of: a) forming a core material, b) forming a capsule material, c) encapsulating the core with the capsule material, d) adding the capsule to a substrate, and e) exposing the capsule to at least one bioactivating agent.

The present disclosure provides an encapsulated liver tissue that can be used in vivo to improve liver functions, in vitro to determine the hepatic metabolism and/or hepatotoxicity of an agent and ex vivo to remove toxic compounds from patients' biological fluid. The encapsulated liver tissue comprises at least one liver organoid at least partially covered with a biocompatible cross-linked polymer. Processes for making the encapsulated liver tissue are also provided.