The present disclosure provides for a cell stabilizing medium which comprises gelatin. The cell stabilizing medium help maintain cell viability, e.g., after thawing of a biological material post-cryopreservation.

[Problem] To provide a cell preparation including mesenchymal stem cells (MSCs) having a high therapeutic effect. [Solution] A method for producing activated mesenchymal stem cells, including a step of culturing MSCs in a medium containing an activator that includes an extract from a mammalian fetal appendage as an active ingredient, using a cell culture carrier having a three-dimensional structure formed of a fiber is provided. A marker for a therapeutic effect of MSCs selected from the group consisting of p16.sup.ink4a, p14.sup.ARF, CDK4, CDK6, RB, and CD47, a method for determining a therapeutic effect using the marker, a method for determining suitability of MSCs to be treated with a treatment for enhancing a therapeutic effect of MSCs, a cell preparation including MSCs, and a method for producing the same are also provided.

A method of forming a tissue. The method includes providing a source of a pre-tissue composition comprising endothelial cells. The method also includes perfusing a culture media into the pre-tissue composition using a plurality of primary channels and a plurality of secondary channels to form the tissue, wherein the endothelial cells are configured to form the secondary channels via vasculogenesis.

Provided is a cell culture sheet. A cell culture sheet according to an embodiment of the present invention includes: a fiber web which has a 3-dimensional network structure formed through the accumulation of support fibers having an average diameter of at most 1.5 μm, and has a basis weight of 1 to 15 g/m.sup.2; and a functional coating layer which is coated on the support fibers exposed on at least one surface of the fiber web, and has a function of promoting one or more of the adhesion, movement, proliferation, and differentiation of cells. Accordingly, cell adhesion is improved due to the large specific surface area and the surface morphology suitable for cells, and the adhered cells are stably supported. Moreover, the cells can be cultured at high density at a high culture efficiency, and can be cultured and recovered without agglomeration caused by forming a thin film.

The present invention relates to a method for fabrication of an extracellular matrix-induced self-assembly and to fabrication of an artificial tissue using same. The method for fabrication of an extracellular matrix-induced self-assembly comprise the steps of: (a) decellularizing and powdering a tissue-derived extracellular matrix (ECM); and (b) adding the decellularized extracellular matrix powder to cells and culturing the cells to form a cell-extracellular matrix powder self-assembly. Accordingly, the self-assembly has characteristics similar to those of extracellular matrix tissues and can be fabricated into three-dimensional artificial tissues 1 cm or greater in size, thus finding advantageous applications as a cell therapy product and an artificial tissue implant.

This disclosure relates to methods for enriching a first population of cells positive for a target moiety and/or a second population of cells positive for the target moiety from a sample, wherein a level of the target moiety among the first population of cells is relatively lower than the level of the target moiety among the second population of cells. The methods of this disclosure may also be adapted to assays for determining distinct populations of cells positive for a target moiety in a sample, and to assays for optimizing enrichment conditions. Last, this disclosure relates to kits of components that may be used to carry out the methods and assays.

A method for micro-tissue encapsulation of cells includes coating a tissue scaffold stamp with an extracellular matrix compound; depositing the tissue scaffold stamp onto a thermoresponsive substrate; seeding the tissue scaffold stamp with a cell culture; incubating the cell culture on the tissue scaffold stamp at a temperature that is specified, wherein the cell culture forms a cell patch that is attached to the extracellular matrix compound; removing the thermoresponsive substrate by lowering the temperature; removing the tissue scaffold stamp from the cell patch to form a micro-tissue structure by dissolving the tissue scaffold stamp in a solvent; folding the micro-tissue structure by suspending the micro-tissue in the solvent to enable the cell patch to fold the micro-tissue structure; collecting the folded micro-tissue structure from the solvent; and administering the folded micro-tissue structure to an organism.

[Problem] An object of the present invention is to produce cancer cell clusters with intrinsic biological properties as cancer tissues, such as morphological polarity and tissue motion polarity, in vitro. [Solution] The present invention relates to a cell culture substrate including a base material and a biocompatible polymer layer, the substrate including a plurality of rough sections on the surface of the substrate, wherein the rough sections are not covered with the biocompatible polymer layer, have a predetermined surface structure with a predetermined shape, and are disposed at predetermined intervals. With the present invention, it is possible to obtain a live cancer cell aggregate having morphological polarity and tissue motion polarity similar to that observed in vivo, by a very easy operation of culturing cancer cells on a cell culture substrate having a predetermined structure, thereby performing live imaging of microtumors in vitro is enabled, which has been conventionally impossible. Moreover, since such a cancer cell aggregate is considered to reproduce a series of flow of development, proliferation, infiltration, metastasis, and recurrence of cancer in vivo, the cancer cell aggregate can be utilized as a research tool in cancer research, or for screening for an anticancer drug.

A tissue engineering material for nerve injury repair, a preparation method therefor and an application thereof. The tissue engineering material for nerve injury repair is an N-cadherin crosslinked linear ordered collagen scaffold. By crosslinking N-cadherin with a linear ordered collagen scaffold, the prepared tissue engineering material can efficiently induce migration of neural stem cells towards an injury region so that the neural stem cells are enriched in the injury region, and can effectively inhibit deposition of inhibitory factors such as chondroitin sulfate proteoglycan, promote differentiation of the neural stem cells into neurons, and then promote recovery of electrophysiological and motion functions. The N-cadherin crosslinked linear ordered collagen scaffold also has a stable ordered topological structure and excellent mechanical properties, and can be used to repair nerve injuries such as spinal cord injury.

The invention relates to a membrane which can be used for cultivating adherent or suspension cells, in particular adherent cells, wherein said membrane allows for the adhesion and proliferation of the cells due to the irradiation of the wet or dry membrane with gamma- or beta-rays or an electron beam in a dose of from 12.5 to 175 kGy in the presence of oxygen. The resulting membrane may be used without any pre-treatment with surface-modifying substances. The invention further relates to a method for preparing said irradiated membrane which can be used for the cultivation of cells, in particular adherent cells, and to methods of using such a membrane for the cultivation of cells, in particular adherent cells.