Disclosed are living, three-dimensional tissue constructs for in vitro scientific and medical research, arrays thereof, and methods of making said tissues and arrays.

Provided herein are methods for directing differentiation of human pluripotent stem cells into a three-dimensional multilayered skin composition comprising an epidermal layer, a dermal layer, and a plurality of cells capable of forming a functional hair follicle. Also provided herein are three-dimensional, multilayered engineered skin compositions and methods of using the same for drug screening, for screening compounds for effects on hair growth, and for other applications.

The present invention aims to provide a method for suppressing differentiation of ganglion cell, amacrine cell, horizontal cell and/or bipolar cell in a neural retina tissue containing photoreceptor precursor and/or photoreceptor, and the like. A method for suppressing differentiation of a ganglion cell, an amacrine cell, a horizontal cell and/or a bipolar cell in a neural retinal tissue containing a photoreceptor precursor and/or a photoreceptor, including a step of culturing a retinal tissue comprising a neural retinal progenitor cell and in any stage between a differentiation stage immediately after emergence of a ganglion cell and a differentiation stage where emergence rate of a cone photoreceptor precursor reaches maximum in a medium containing a thyroid gland hormone signal transduction pathway agonist.

Provided herein are methods for directing differentiation of human pluripotent stem cells into a three-dimensional multilayered skin composition comprising an epidermal layer, a dermal layer, and a plurality of cells capable of forming a functional hair follicle. Also provided herein are three-dimensional, multilayered engineered skin compositions and methods of using the same for drug screening, for screening compounds for effects on hair growth, and for other applications.

The present invention is directed to a method of producing a tissue graft, comprising at least steps of providing a gel, seeding the gel with cells of at least a first and/or cells of a second type, and culturing of the cells of the first and/or cells of the second type in said gel until the formation of at least one first biostructure in the gel by the cells of the first type and/or the cells of the second type.

A sheet for covering a wound includes a laminate of a serosal membrane and a cell sheet. The sheet for covering a wound has a proper thickness and strength. The sheet does not flow out from the wound site and can be fixed to the wound site by suture or anastomosis, if necessary. The sheet can be stably engrafted onto a wound region.

The invention provides for engineered intestinal construct and methods of making these constructs. The invention also provides for methods of treating short bowel syndrome or methods of repairing an intestine after resection comprising inserting an engineered intestinal construct into the intestine of a subject in need.

Provided are skin constructs and methods of making and using the same, such as for wound treatment and/or compound testing, including compound testing for efficacy, toxicity, immune response, penetration, irritation and/or metabolism testing of drug candidates or compositions such as cosmetics.

The disclosure provides a device for developing organized tissue strips, such as cardiac tissue strips, for high-throughput assays of functional performance and the methods involved in fabricating, assembling, implementing, utilizing and analyzing data from such assays. The disclosure further provides systems for constructing such devices, systems comprising those devices comprising cells and extracellular matrix material for developing organized tissue strips or comprising the devices and organized tissue strips. The disclosure further provides methods for assaying a property of a tissue strip, such as contractile force.

In some embodiments, the present invention provides tissue compositions including a first silk scaffold comprising a plurality of epithelial cells, a second silk scaffold comprising a plurality of stromal cells, and a plurality of neurons. In some embodiments, provided compositions can function as physiologically relevant corneal model systems for, inter alia, testing of therapeutics for corneal disease and/or injury and production of functional corneal tissue (e.g., for transplant, etc). The present invention also provides methods for making and using provided compositions.