The present disclosure provides expression constructs designed to provide for expression of therapeutic proteins from engineered cells. The engineered cells may be encapsulated into implantable elements that allow for the therapeutic protein to be released into from the capsule while protecting the cell from the immune system of a patient into which the capsule is implanted.

The present specification provides a spontaneous-contracting cardiac organoid, a method for manufacturing the organoid, and a method for evaluating drug toxicity by using same, the cardiac organoid comprising: a chamber in which a fluid is stored; a first pipe connected to the chamber so that the fluid flows therethrough; a second pipe connected to the chamber so that the fluid is discharged therethrough; and a valve formed on the first pipe so as to spontaneously open/close an inflow pipe.

Disclosed are methods of producing organoids in the absence of any exogenous extracellular matrix or in the presence of an exogenous extracellular matrix at a concentration lower than gelling concentration, using microcontainers sealed with a hydrogel lid as well as organoids produced by this technique.

A method for the mass proliferation of urine-derived multipotent cells and a medium composition for the mass proliferation of urine-derived multipotent cells according to the present invention can be used to massively proliferate urine cells by efficiently isolating the same even from urine that has been left alone for a long period of time, and can be used to produce multipotent cells having characteristics of epithelial cells, mesenchymal cells, and stem cells.

A method for generating a heart organoid is provided. The method includes forming a cellular aggregate of pluripotent stem cells, activating Wnt signaling in the cellular aggregate to cause the cellular aggregate to differentiate into a three-dimensional cardiac mesoderm, and inhibiting the Wnt signaling in the cardiac mesoderm to form the heart organoid. The heart organoid includes myocardial tissue, endocardial tissue defining at least one chamber, and epicardial tissue disposed on at least an outer surface of the myocardial tissue. The heart organoid beats. Heart organoids prepared in accordance with the method are also provided.

A method for producing exosomes in a large-scale by using a cyclic tensile bioreactor to stimulate cells to release exosomes. In addition, the exosome having an anti-HLA-G protein specific for cancer is used as a delivery vehicle to deliver therapeutic agents for treating cancer.

The disclosure describes global transcriptome profiling in human vascular endothelial cells upon THSD1 knockdown and identification from these studies of specific genes and pathways that are THSD1. The analysis highlights a role for THSD1 in regulating endothelial to mesenchymal transition and other pathways. The analysis also demonstrates that endothelial cell injury is the first event of an intracranial aneurysm. The disclosure provides novel cell lines and reagents used for better understanding the molecular mechanism of THSD1 biology.

The present invention provides, in order to prepare matured hepatocytes analogous in various points to primary hepatocytes, a method for preparing hepatocytes or cells that can be differentiated into hepatocytes from pluripotent stem cells, comprising the steps of: (1) culturing the pluripotent stem cells in a medium containing an activator of an activin receptor-like kinase-4,7; (2) culturing the cells obtained in the step (1) in a medium containing a bone morphogenetic factor and a fibroblast growth factor; (3) culturing the cells obtained in the step (2) in a medium containing an activator of a hepatocyte growth factor receptor and an activator of an oncostatin M receptor; and (4) culturing the cells obtained in the step (3) to obtain hepatocytes or cells that can be differentiated into hepatocytes, wherein in at least one of the steps (2), (3) and (4), cells are cultured on a high-density collagen gel membrane.

Provided herein are cross-reactive antibodies (or antigen binding fragments thereof) that bind to human CTLA4, activatable antibodies that bind to human CTLA4, nucleic acid molecules encoding the same, pharmaceutical compositions thereof, and methods of their therapeutic use (e.g., for treatment of cancer).

Methods for generating cells of the inner ear, e.g., hair cells and supporting cells, from stem cells, e.g., mesenchymal stem cells, are provided, as well as compositions including the inner ear cells. Methods for the therapeutic use of the inner ear cells for the treatment of hearing loss are also described.