Provided are: a production device by which a cell structure having a three-dimensional structure is produced using a plurality of linear members; a production system therefor; and a production method therefor. The production device 100 comprises a top plate 110, pins 120A to 120D, a first slide plate 130, a second slide plate 140, a stopper 150, a base plate 160, an outer peripheral needle-shaped member 170 and an inner peripheral needle-shaped member 180. Cell aggregates 400 are put into a three-dimensional tubular space S1 that is defined by the outer peripheral needle-shaped member 170 and the inner peripheral needle-shaped member 180. Then, the top plate 110 is pressed downward on the accumulated cell aggregates 400. Thus, the cell aggregates 400 are immersed in a culture solution 210 and stuck together so that a tubular cell structure 500 is produced using the three-dimensional space S1 as a mold.

Provided herein are cytoplasts, compositions comprising cytoplasts, methods of using cytoplasts, and methods of treating a subject, such as providing benefits to a healthy or unhealthy subject, or treating or diagnosing a disease or condition in a subject. In some embodiments, methods of treating a subject include: administering to the subject a therapeutically effective amount of a composition comprising a cytoplast. Also, provided herein are compositions (e.g., pharmaceutical compositions) that include a cytoplast. Also, provided herein are kits comprising instructions for using the compositions or methods.

The present invention relates to an edible and sterilizable macroporous three-dimensional (3D) tissue engineering scaffolds comprising a network of cross-linked biocompatible polymer, preferably a natural polymer. Moreover, the scaffold of the invention further comprises additives and living cells which adhere and proliferate, colonizing the entire surface of the scaffold and giving rise to a raw material for the later formation of tissue with high nutritive content and/or cultured meat, that may be subsequently processed into food for animal or human consumption without requiring modification or removal of the cells form the scaffold. Method of using the scaffolds to make cultured meat and/or tissues for being processed as food comprising the scaffold, are also described herein.

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.

The present disclosure relates to tissue engineering, and more particularly to a method for treating or repairing rotator cuff or other tendon tears or damage using scaffold-free 3-dimensional engineered tendon constructs.

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.

The present invention provides a culture method capable of maturing an organoid through long-term culture, and suitable for producing a conformational organ. The culture method of the present invention is a method for culturing an organoid and/or cells constituting an organ immobilized in a chamber with a culture fluid perfused, and the culture fluid is perfused in such a manner as to generate a turbulent flow in the chamber.

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 of producing a cell mass by three-dimensional culture of primary cancer cells having proliferative ability and properties of handleability, versatility, and high-throughput performance, in which a tumor tissue is used as a starting material, proliferation of cells such as fibroblasts other than cancer cells is inhibited, and the cell mass includes primary cancer cells as a main component. The object is achieved by providing a method of producing a cell mass by three-dimensional culture of primary cancer cells using a tumor tissue, including: a three-dimensional culture step of culturing cells obtained from the tumor tissue in a medium containing a 5% v/v or less extracellular matrix on a substantially low-adhesive cell culture substrate.

The present invention relates to 3D brain organoids, uses thereof, methods and culture medium for generating such organoids. An aspect of the invention provides brain organoids and methods of generating such organoids with bilaterally symmetric optic vesicles, containing both neuronal and non-neuronal cell types, and exhibiting functional circuitry. These organoids can be generated within short time intervals (e.g., 50 days) and therefore are useful for medical modelling and applications.