The present invention relates to stem cell-derived microvesicles with enhanced efficacy, a use thereof, and a method for enhancing efficacy, and more particularly, to a use of stem cell-derived microvesicles with an enhanced expression level of microRNAs for the prevention or treatment of stroke, and a method for promoting the production of microRNAs of stem cell-derived microvesicles and enhancing efficacy, and a method for promoting the production of stem cell-derived microvesicles and microRNAs within the microvesicles and enhancing the efficacy of stem cells and microvesicles thereof by 3-dimensionally culturing or ischemically stimulating stem cells. Since the method according to the present invention has excellent effects capable of promoting the production of stem cell-derived microvesicles and microRNAs in the microvesicles and capable of enhancing the efficacy of stem cells or microvesicles isolated therefrom, it is possible to obtain stem cell-derived microvesicles containing high levels of materials including therapeutic microRNAs efficiently and in large quantities through this, and thus, the microvesicles are expected to be able to be usefully used in related research fields and future clinical settings.

The present disclosure provides, in various aspects, a method of forming a prefabricated innervated pre-vascularized pre-laminated (PIPP) flap having a stoma or lumen. The method includes providing a cell construct including skin cells and/or mucosa cells. The method further includes forming an integrated in vivo composite at a donor site by grafting the cell construct onto a muscle. The method further includes stabilizing the composite on an obturator component. The method further includes developing a microvascular system in the composite by retaining it in vivo at the donor site for a predetermined period of time. The method further includes removing the obturator component from the stoma or lumen. In certain aspects, the present disclosure also provides a method of restoring a defect including damaged or surgically removed soft tissue using a PIPP flap. In certain aspect, the present disclosure also provides an obturator component for maintaining the stoma or lumen.

The present disclosure relates to a nanofiber structure for cell culture, a method for manufacturing the structure, and a cell analysis device including the nanofiber structure for cell culture. The structure includes a cell culture layer made of nanofibers; and a spacer protruding upward from a surface of the cell culture layer, wherein the spacer divides a region on the cell culture layer into at least two culturing regions, wherein the spacer is made of the same nanofibers as the cell culture layer and thus has a cell migration channel defined therein.

This application relates to a method of making a cell construct, comprising a) plating a plurality of cells on a substantially flat surface; b) growing the plurality of cells to at least 80% confluent to form a cell sheet with intercellular linkages; c) applying a culture medium having a pH of about 5 to about 6.8 to the cell sheet; d) replacing the culture medium of step c) with a culture medium having a pH of about 7.5 to about 8.5; and e) replacing the culture medium of step d) with a culture medium having a pH of about 7 to about 7.7, to obtain a substantially planar untethered cell sheet. Also provided is a cell construct formed according to the method and uses thereof.

A bioreactor and methods for use can include a microfibrous scaffold, that can be made of a composite bioink, and that can have endothelial cells directly embedded within the scaffold using an additive manufacturing process. The scaffold can further be seeded with cardiomyocytes. The hydrogel scaffold can be composed of a plurality of serpentine layers, with each serpentine layers, which can be placed on each other in a cross-hatch configuration, so that the primary axes of successive layers are perpendicular. This configuration can establish an aspect ratio for the scaffold, which can be selectively varied. For greater strength, the successive layers that have a primary axis in the same direction can be placed in the scaffold so that they are slight offset from each other. The scaffold can be placed in the bioreactor with perfusion, for use in cardiovascular drug screening and other nanomedicine endeavors.

The present invention provides a hydrogel capsule comprising a cell, a protein, and a cross-linking agent; wherein the cell is within a first core layer comprising the protein; and wherein the first core layer is surrounded by a second layer comprising the protein and the cross-linking agent. The invention further provides the hydrogel capsule for use in therapy, prognosis and diagnosis, a method for culturing cells, a method for differentiating cells, and method for producing the hydrogel capsule. The hydrogel capsules of the invention are particularly useful for encapsulating pancreatic islets

Provided is a method of producing an osteoblast construct from iPS cells, the method including the steps of: (1) inducing formation of an embryoid body by subjecting undifferentiated iPS cells to non-adherent culture; (2) inducing differentiation of the iPS cells into mesodermal cells by subjecting the embryoid body of the iPS cells obtained in the step (1) to non-adherent culture; and (3) inducing differentiation into osteoblasts by subjecting the mesodermal cells of the iPS cells obtained in the step (2) to non-adherent culture, wherein the steps (1) and (2) are each performed using a culture vessel comprising a bottom surface and a circular side wall arranged upright on the bottom surface, the bottom surface having a plurality of depressed portions arranged independently of each other.

Organs-on-chips are microfluidic devices for culturing living cells in micrometer sized chambers in order to model physiological functions of tissues and organs. Engineered patterning and continuous fluid flow in these devices has allowed culturing of intestinal cells bearing physiologically relevant features and sustained exposure to bacteria while maintaining cellular viability, thereby allowing study of inflammatory bowl diseases. However, existing intestinal cells do not possess all physiologically relevant subtypes, do not possess the repertoire of genetic variations, or allow for study of other important cellular actors such as immune cells. Use of iPSC-derived epithelium, including IBD patient-specific cells, allows for superior disease modeling by capturing the multi-faceted nature of the disease.

The present disclosure relates to tissue supports for use with engineered tissues and organoids, such as cardiac organoid chambers. In an embodiment of the present disclosure, the tissue supports are provided with a fluid-impermeable resilient member that is resiliently deformable during testing by cultured tissues formed on the surface of the tissue support.

A spheroid tissue microarray comprises an array of tissue spheroids embedded within a porous mold. The product may be impregnated with a wax or resin and sectioned, and contains spheroids which are precisely located in a regular geometric grid. A method of manufacturing a spheroid tissue microarray comprises the steps of: forming a mold of porous material from liquid mold material in a casting mold, and allowing the liquid mold material to set; removing the porous mold from the casting mold; topping up the porous mold with further liquid mold material, and allowing recesses to form in the surface of the mold by the drawing-in of liquid mold material through shrinkage as the liquid mold material sets; placing tissue spheroids into the recesses in the surface of the porous mold; and sealing the tissue spheroids within the mold by topping off with liquid mold material and allowing the liquid mold material to set. An alternative method comprises the steps of: forming a mold of porous material from liquid mold material in a casting mold; allowing the liquid mold material to set; removing the porous mold from the casting mold; placing spheroids in recesses at the bases of wells in the mold of porous material; and sealing the spheroids within the porous mold by adding further porous material on top of the spheroids; wherein the recesses at the bases of the wells in the porous material are formed by protrusions of the casting mold carrying further, nipple-shaped, protrusions.