A biological system for generating and preserving a repository of personalized, humanized transplantable cells, tissues, and organs for transplantation, wherein the biological system is biologically active and metabolically active, the biological system having genetically reprogrammed cells, tissues, and organs in a non-human animal for transplantation into a human recipient, wherein the non-human animal does not present one or more surface glycan epitopes and specific sequences from the wild-type swine's SLA is replaced with a synthetic nucleotides based on a human captured reference sequence from a human recipient's HLA.

This disclosure relates to methods, polynucleotides, vectors, viral particles, cells, and systems or the engineering of human tissues. One aspect of the disclosure relates to using lineage-specific miRNA binding molecules to bias tissue lineage. Another aspect of the disclosure relates to using lineage-specific transcription factor overexpression to bias tissue lineage.

The present disclosure is directed to methods of producing dorsal forebrain organoids having cores with a very low incident of apoptotic and hypoxic cells and having highly similar cell types and cell type prevalence. The present disclosure is also directed to compositions comprising such organoids and the use of such organoids for the screening of agents.

The apparatuses described herein relate to preparation of a meat product. Apparatuses, systems comprising the apparatuses, and methods of making and use the systems and apparatuses are described herein. These are useful for controlling one or more of growth on and separation of a meat product from an enclosed substrate. The apparatuses and systems are configured to receive fluid and grow the meat product and/or separate the meat product from the substrate in a scalable manner.

Engineered, living, three-dimensional liver tissue constructs comprising: one or more layers, wherein each layer contains one or more liver cell types, the one or more layers cohered to form a living, three-dimensional liver tissue construct. In some embodiments, the constructs are characterized by having at least one of: at least one layer comprising a plurality of cell types, the cell types spatially arranged relative to each other to create a planar geometry; and a plurality of layers, at least one layer compositionally or architecturally distinct from at least one other layer to create a laminar geometry. Also disclosed are arrays and methods of making the same. Also disclosed are engineered, living, three-dimensional liver tissue constructs for use in the augmentation or restoration of one or more liver functions, by in vivo delivery of tissue or utilization of tissue in an extracorporeal device.

The present invention relates to a method for fabrication of a three-dimensional lung organoid comprising human stem cell-derived alveolar macrophages. Specifically, a lung organoid is fabricated by co-culturing cells not expressing the definitive endoderm marker CRCX4 according to a fabrication method of the present disclosure. The lung organoid comprises type 1 and type 2 alveolar epithelial cells as well as alveolar macrophages and realizes infectious or inflammatory responses unlike conventional lung organoids that contain no immune cells and as such, can be advantageously used in studying mechanisms of related lung diseases, excavating biomarkers, developing therapeutic agents, and so on.

The present invention relates to an organoid and, more specifically, to an organoid and a use thereof, the organoid being produced using a carrier for cell culture which comprises microcapsules containing gelatin, a natural polymer, an oil, and an oil thickener. When used as a carrier for cell culture in culturing cells, the microcapsules containing a natural oil, according to the present invention, have the effects of improving adhesion and survival of the cells and inducing maturation of the cultured cells. The organoid produced by culturing cells using the carrier for cell culture has been confirmed to have the function of the organ concerned and, when treated with a drug, react to the toxicity of the drug and thus may be variously employed in the development of new drugs, disease research, and the field of artificial organ development.

An in vitro microfluidic device includes a device configured to model a blood-brain barrier. The device includes a center well in fluidic communication with each of an inlet and an outlet. Each of the center well, inlet, and outlet includes a porous membrane that separates a “blood” portion (a fluid flow portion) from a “brain” portion (a fluid containing portion). The porous membrane is seeded with endothelial cells such as the human venule endothelial cells (HUVECs) on the blood side, and with astrocytes on the brain side, to accurately model the blood-brain barrier. Fluid flows between the inlet, the center well, and the outlet to test the permeability of the porous membrane, thereby providing an accurate in vitro model of a blood-brain barrier.

The present disclosure relates to a method for obtaining human brain-like endothelial cells by contacting a population of cells isolated from stem cells with a differentiation medium to obtain endothelial cells and co-culturing said endothelial cells with pericytes, with cells of the neurovascular unit or with a pericytes conditioned medium, to obtain brain-like endothelial cells. The present disclosure also relates to the use of the brain-like endothelial cells as an in vitro model of human blood-brain barrier and a kit for measuring blood-brain barrier permeability of a substance, comprising in vitro human endothelial cells.

The present disclosure provides ex vivo chamber-specific cardiac tissues, methods for generating the cardiac tissues in a bioreactor, and methods of using the cardiac tissues. Examples of cardiac tissues that can be generated include, but are not limited to, atrial tissues, ventricular tissues, and composite tissues having an atrial tissue connected to a ventricular tissue.