A microcarrier for cell culture and expansion is provided. The microcarrier includes decellularized mammalian tissue. Further, the microcarrier has an average particle size ranging from about 10 micrometers to about 600 micrometers. A method of forming a decellularized mammalian tissue microcarrier for cell culture and expansion is also provided, along with a method for treating a mammalian tissue defect via a decellularized mammalian tissue microcarrier on which cells from the same tissue type as the decellularized mammalian tissue are expanded.

An object of the present invention is to provide a method of manufacturing a large number of uniform cell structures for a short period of time. According to the present invention, provided is a method of manufacturing a cell structure, including: a step of adding a mixture of biocompatible macromolecular blocks, cells, and a liquid medium to a first culture container having a culture surface on which the plurality of recessed portions are formed and a side wall part standing on an outer periphery of the culture surface such that a liquid surface of the mixture is over the culture surface; a step of allowing a first culture container to stand and forming a cell structure in the recessed portion; and a step of stirring and culturing a content of the first culture container in a second culture container including stirring means.

An elongated or fiber-supported multicellular aggregation of multipotent cells, wherein multipotent cells are arranged in an oblong or longish arrangement with an aspect ratio of a prolate dimension to a perpendicular dimension of at least 2:1, or supported by a fibrous structure, and wherein the aggregate contains cells at different stages of differentiation, and the aggregate contains polar cells; methods of generating such aggregates; methods of developing the aggregates further into tissue organoids and kits for such methods.

Provided is a method that achieves control of embryoid body size and can induce differentiation in a state where the embryoid body size is controlled, by using a cell culture chamber having a plurality of microchambers formed therein. A culture method for causing differentiation of pluripotent mammalian cells uses a cell culture chamber (10) having a plurality of microchambers (11) formed on a culture surface. The cell culture chamber (10) has a culture surface formed of spaces in which the microchambers (11) have a space structure with a height of 10 m to 500 m and a bottom area of 100 m.sup.2 to 1 mm.sup.2. The culture method for causing differentiation of pluripotent mammalian cells includes culturing pluripotent mammalian cells to obtain a cell population at least partially differentiated into endoderm lineage cells, by using the cell culture chambers (10).

The present invention provides tissue scaffolds, methods of generating such scaffolds, and methods of use of such scaffolds to generate aligned and functional neural tissues for use in methods including regenerative medicine, wound repair and transplantation.

The invention relates to devices, methods, kits, and compositions for in vitro generation of three-dimensional micro-tissues that are accurate models of heart, skeletal muscle, neuronal, and other tissues.

An object of the present invention is to provide a cell structure for brain damage treatment which does not contain glutaraldehyde and in which it is possible to exhibit a sufficient effect of treating brain damage, a production method thereof, and a brain damage treatment agent. According to the present invention, there is provided a cell structure for brain damage treatment which contains biocompatible macromolecular blocks and at least one kind of cell and in which a plurality of the biocompatible macromolecular blocks are disposed in gaps between a plurality of the cells, in which the tap density of the biocompatible macromolecular block is 10 mg/cm.sup.3 to 500 mg/cm.sup.3 or a value obtained by dividing a square root of a cross-sectional area in a two-dimensional cross-sectional image of the biocompatible macromolecular block by a peripheral length is 0.01 to 0.13.

The invention relates to methods for developing and maintaining organoids and the organoids produced thereby.

The present disclosure relates to a human cardiac tissue construct, to the method for producing thereof and its uses in disease modelling, compound screening and properties evaluation, and/or therapeutic uses in heart regeneration. It further relates to a perfusion bioreactor with electrical stimulation capabilities and its use in the production of said human cardiac tissue construct. In still a further aspect, the disclosure provides a method for the non-destructive evaluation of electrophysiological activity in a cellular construct, such as a cardiac tissue construct of the disclosure.

The presently disclosed subject matter relates generally to the delivery of electrical stimuli via cell-penetrating nanoelectrodes. Such electrical stimuli leads to differentiation of cells, including but not limited to adipose derived stem cells, to neural lineage, specifically to neural cells.