The present disclosure provides activatable and detectable membrane-interacting peptides that, following activation, can interact with phospholipid bilayers, such as cell membranes. The present disclosure also provides methods of use of such compounds. The compounds of the present disclosure are of the general structure X.sup.1a-A-X.sup.2-Z-X.sup.1b, where A is a membrane-interacting peptide region having a plurality of nonpolar hydrophobic amino acid residues that, following separation from portions Z, is capable of interaction with a phospholipid bilayer; Z is an inhibitory peptide region that can inhibit the activity of portion A; X.sup.2 is a cleavable linker that can be cleaved to release cleavage products from the compound; and X.sup.1a and X.sup.1b are optionally-present chemical handles that facilitate conjugation of various cargo moieties to the compound. Prior to cleavage of the composition at X.sup.2, the composition acts as a promolecule that does not associate with cellular membranes to a significant or detectable level. Following cleavage at cleavable linker X.sup.2, the cleavage product including portion A is free to interact with a phospholipid bilayer (e.g., a cell membrane), and thus accumulate at a site associated with a cleavage-promoting environment. Detection of the membrane-associated cleavage product can be accomplished by detection of a moiety attached through X.sup.1a and/or X.sup.1b. Such compositions can be used in a variety of methods, including, for example, use in directly imaging active clotting within a subject.

Disclosed are methods for making a vascularized hollow organ derived from human intestinal organoid (HIOs). The HIOs may be obtained from human embryonic stem cells (ESC's) and/or induced pluripotent stem cells (iPSCs), such that the HIO forms mature intestinal tissue. Also disclosed are methods for making a human intestinal tissue containing a functional enteric nervous system (ENS).

The usage of a stem cell in preparation of a tooth-like structure is provided. And a culture medium, a method for preparing an epithelial-like cell, a kit for preparing an ameloblast, a method for preparing an ameloblast are also provided. Specifically, the culture medium comprises a basal medium, which is DMEM/F12 medium; N2 supplement; retinoic acid; and BMP-4.

Disclosed herein are cell cultures and enriched cell populations of endocrine precursor cells, immature pancreatic hormone-expressing cells and mature pancreatic hormone-expressing cells. Also disclosed herein are methods of producing such cell cultures and cell populations.

Described herein are chemically defined, adherent culture protocols for generating functional motor neurons characteristic of diverse hindbrain and spinal cord regions, with high efficiency.

Methods for generating functional brain microvascular endothelial cells (BMECs) under chemically defined, serum-free conditions are provided. In particular, efficient and cost-effective methods for generating functional BMECs under chemically defined culture conditions are provided. BMECs obtained according to the methods provided herein are suitable for in vitro blood brain barrier (BBB) formation.

Methods are provided for the production of retinal ganglion (RG) progenitor cells and mature RG cells from pluripotent stem cells optionally under feeder-free conditions, and further optionally under xeno-free conditions. Additionally provided are compositions of RG progenitor cells and mature RG cells, as well as methods of use thereof including therapeutic use thereof. Exemplary methods may produce substantially pure populations and cultures of RG progenitor cells and mature RG cells.

The present invention provides cell populations that are enriched for mesendoderm and mesoderm, and cell populations that are enriched for endoderm. The cell populations of the invention are useful for generating cells for cell replacement therapy. The present invention further provides a method of generating hepatocytes, cell populations enriched for hepatocytes, and a method of hepatocyte replacement therapy.

The present invention provides methods to promote the differentiation of pluripotent stem cells. In particular, the present invention provides an improved method for the formation of pancreatic endoderm, pancreatic hormone expressing cells and pancreatic hormone secreting cells. The present invention also provides methods to promote the differentiation of pluripotent stem cells without the use of a feeder cell layer.

Disclosed are methods of inducing formation of a gastric cells and/or a gastric tissue, such as in the form of a gastric organoid. The formation of gastric cells and/or tissue may be carried out by the activating and/or inhibiting of one or more signaling pathways within a precursor cell. Also disclosed are methods for using the disclosed gastric cells, gastric tissues, and/or gastric organoids derived from precursor cells.