Abstract: Provided is a culture chamber capable of preparing spheroids with a uniform size with high efficiency and having a micro-space structure which is designed to facilitate replacement of a medium and harvesting of cells. The culture chamber includes a plurality of recesses (10) each formed of a bottom portion (11) and an opening portion (12). The bottom portion (11) has one of a hemispherical shape and a truncated cone shape and the opening portion (12) is defined by a wall that surrounds an area from a boundary between the opening portion (12) and the bottom portion (11) to an end of each of the recesses (10), the wall having a taper angle in a range from 1 degree to 20 degrees. An equivalent diameter of the boundary is in a range from 50 ?m to 2 mm and a depth from a bottom of the bottom portion (11) to the end of each of the recesses is in a range from 0.

Abstract: A control system includes a terminal device including a first communication unit configured to perform first Bluetooth communication and second Bluetooth communication, and a printing apparatus including a second communication unit that is connected by pairing to the terminal device to perform the second Bluetooth communication with the first communication unit, wherein the terminal device performs the first Bluetooth communication in a state where no pairing connection is made with the printing apparatus, and transmits a notification instruction command to the printing apparatus through the first communication unit, and wherein the printing apparatus performs a notification operation based on the notification instruction command when receiving the notification instruction command through the second communication unit based on the first Bluetooth communication.

Abstract: Provided is a culture chamber that includes a plurality of recesses each formed of a bottom portion and an opening portion. The bottom portion has a hemispherical shape or a truncated cone shape. The opening portion is defined by a wall that surrounds an area from a boundary between the opening portion and the bottom portion to an end of each of the recesses, the wall having a taper angle in a range from 1 to 20 degrees. An equivalent diameter of the boundary is from 50 ?m to 2 mm and a depth from a bottom of the bottom portion to the end of each of the recesses is from 0.6 or more times to 3 or less times the equivalent diameter, and the wall defining the opening portion forms a surface continuous to the bottom portion. An inclination of the continuous surface changes at the boundary.

Abstract: The present invention provides a marker gene capable of detecting the undifferentiated cells that remain or become included in a differentiated cell population. Undifferentiated cells present in a differentiated cell population are detected by using at least one gene selected from the group consisting of LINC00678 and PRDM14 as an undifferentiation marker. A method of detecting undifferentiated cells; a method of using the gene as an undifferentiation marker; and a kit for detecting undifferentiated cells. A method of selecting an undifferentiated cell clone is also provided.

Abstract: The present invention provides a sensitive and simple detection method, and a kit therefor, which detects residual undifferentiated human pluripotent stem cells in an intermediate product and/or a final product of a regenerative medical products, using an isothermal nucleic acid amplification method, and specifically, a LAMP method. A method for detecting presence or absence of undifferentiated cells in a non-undifferentiated cell population, wherein RNA derived from an undifferentiation marker gene exhibiting a significant difference in expression level between the undifferentiated cells and the non-undifferentiated cells in a sample containing a nucleic acid derived from the cell population of interest is detected by the isothermal nucleic acid amplification method.

Abstract: A cell evaluation method includes acquiring a first evaluation index and a first index calculated using the first evaluation index with respect to comparative target cells in a culture process including a cell differentiation-inducing process in which cell differentiation is induced, calculating a second index on the basis of the first evaluation index with respect to evaluation target cells different from the comparative target cells, and evaluating differentiation of the evaluation target cells by comparing the first index with the second index.

Abstract: The present invention provides a method of constituting a tissue construct in vitro using a tissue without depending on scaffold materials. A method of integrating a biological tissue with a vascular system in vitro, comprising coculturing a biological tissue with vascular cells and mesenchymal cells. A biological tissue which has been integrated with a vascular system by the above-described method. A method of preparing a tissue or an organ, comprising transplanting the biological tissue described above into a non-human animal and differentiating the biological tissue into a tissue or an organ in which vascular networks have been constructed. A method of regeneration or function recovery of a tissue or an organ, comprising transplanting the biological tissue described above into a human or a non-human animal and differentiating the biological tissue into a tissue or an organ in which vascular networks have been constructed.

Abstract: The disclosure provides a method for producing hepatocytes or hepatic progenitor cells; a method for suppressing hepatocyte aging using a drug causing histone hyperacetylation; a hepatocyte anti-aging agent; a method for increasing hepatocyte plasticity; and a drug for increasing hepatocyte plasticity.

Abstract: Provided is a culture chamber that includes a plurality of recesses each formed of a bottom portion and an opening portion. The bottom portion has a hemispherical shape or a truncated cone shape. The opening portion is defined by a wall that surrounds an area from a boundary between the opening portion and the bottom portion to an end of each of the recesses, the wall having a taper angle in a range from 1 to 20 degrees. An equivalent diameter of the boundary is from 50 ?m to 2 mm and a depth from a bottom of the bottom portion to the end of each of the recesses is from 0.6 or more times to 3 or less times the equivalent diameter, and the wall defining the opening portion forms a surface continuous to the bottom portion. An inclination of the continuous surface changes at the boundary.

Abstract: Provided is a coating-fixing agent for transplanting a cell or a tissue onto the surface of an organ, intestinal membrane, peritoneal membrane, etc. Provided are: a formulation for coating and fixing a graft, the formulation comprising alginate; a formulation kit for coating and fixing a graft, comprising a formulation containing alginate and a divalent or higher valent metal salt in combination; and a method for transplanting a graft, comprising: transplanting the graft to a transplant site of a human or a non-human animal, and coating the graft with alginate.

Abstract: The present invention provides a method of constituting a tissue construct in vitro using a tissue without depending on scaffold materials. A method of integrating a biological tissue with a vascular system in vitro, comprising coculturing a biological tissue with vascular cells and mesenchymal cells. A biological tissue which has been integrated with a vascular system by the above-described method. A method of preparing a tissue or an organ, comprising transplanting the biological tissue described above into a non-human animal and differentiating the biological tissue into a tissue or an organ in which vascular networks have been constructed. A method of regeneration or function recovery of a tissue or an organ, comprising transplanting the biological tissue described above into a human or a non-human animal and differentiating the biological tissue into a tissue or an organ in which vascular networks have been constructed.

Abstract: The present invention provides a means for reconstituting tissues and organs having mature functions. A method of preparing a tissue or an organ, comprising coculturing an organ cell with a vascular endothelial cell and a mesenchymal cell, generating an organ bud, transplanting the organ bud into a non-human animal, and then isolating from the non-human animal the transplanted organ bud-derived tissue or organ.

Abstract: The present invention provides a prophylactic and/or therapeutic agent for diseases accompanied by fibrosis. A pharmaceutical composition for preventing and/or treating a disease accompanied by fibrosis in an organ and/or a tissue, which comprises a cell mixture and/or a cell condensate comprising mesenchymal cells and vascular cells (and hepatocytes, optionally). An agent capable of inhibiting organ and/or tissue fibrosis, which comprises both mesenchymal cells and vascular cells or a cell condensate thereof. By transplanting into a subject a cell mixture and/or a cell condensate comprising mesenchymal cells and vascular cells (and optionally, hepatocytes), expression levels of fibrolysis enzymes (fibrolytic factors) such as MMP1 or MMP13 are elevated, which eventually enables inhibition of fibrosis in an organ and/or a tissue, as well as prevention and/or treatment of a disease accompanied by fibrosis in an organ and/or a tissue.

Abstract: A cell culture container includes a storage container, a cell culture area, a culture solution supply unit, and a discharge unit. The cell culture area is a region for culturing cells, and is provided in the storage container. The culture solution supply unit supplies the culture solution into the cell culture area at a flow rate equal to or less than a predetermined flow rate. The discharge unit discharges the liquid in the cell culture area to the outside of the storage container. A rectification unit is a structure in which a plurality of outflow ports are uniformly arranged in a direction perpendicular to the flow direction of the culture solution from the culture solution supply unit to the discharge unit.

Abstract: The present invention provides a marker gene capable of detecting the undifferentiated cells that remain or become included in a differentiated cell population. Undifferentiated cells present in a differentiated cell population are detected by using at least one gene selected from the group consisting of ESRG, VSNL1, THY1, SFRP2, SPP1, USP44 and CNMD as an undifferentiation marker. A method of detecting undifferentiated cells; a method of using the gene as an undifferentiation marker; and a kit for detecting undifferentiated cells. A method of selecting an undifferentiated cell clone is also provided.

Abstract: A tissue structure for enabling comprehensive understanding of gene patterns of mature cells and a method of preparing the tissue structure are provided. A tissue structure is obtained by co-culturing an endodermal, ectodermal, or mesodermal cell derived from a stem cell and at least one cell and/or factor selected from the group consisting of a vascular cell, a mesenchymal cell, a factor secreted by a vascular cell, a factor secreted by a mesenchymal cell, and a factor secreted when both a vascular cell and a mesenchymal cell exist. A value obtained by assay of a plurality of functions using a Pearson product-moment correlation coefficient is closer to a value of a cell or biological tissue sampled from an adult than a value of a cell or biological tissue sampled from a fetus.

Abstract: The present invention provides a method of fusing cell masses. A method of fusing cell masses, comprising seeding cell masses on a plane capable of cell adhesion and culturing the cell masses as a culture medium is fed from both the obverse and reverse sides of the cell mass-seeded plane.

Abstract: The present invention solves the following problems [1] to [3] found in conventional methods of preparing a three dimensional structure (organ primordium) by coculturing functional cells with umbilical cord-derived vascular endothelial cells and bone marrow-derived mesenchymal cells: [1] the quality of resultant organ primordia varies greatly depending on donors; [2] the growth capacities of cell sources are limited; and [3] it is difficult to secure immunocompatibility because cells are derived from different sources. An organ bud prepared from vascular cells, mesenchymal cells and tissue or organ cells, wherein each of the vascular cell, the mesenchymal cell and the tissue or organ cell has been induced from pluripotent stem cells. A method of preparing an organ bud, comprising culturing vascular cells, mesenchymal cells and tissue or organ cells in vitro, wherein each of the vascular cell, the mesenchymal cell and the tissue or organ cell has been induced from pluripotent stem cells.

Abstract: To provide a cell culture kit including cultured living cells of various donors, and a manufacturing method thereof. The cell culture kit includes a culture plate and living cells cultured thereon. The culture plate includes a plurality of microchambers (33) and living cells derived from various donors are adhered to surfaces of the plurality of microchambers (33). Specifically, living cells D1, D2, and D3 derived from various donors are adhered to the plurality of microchambers (33). In each microchamber (33), living cells derived from one donor or living cells derived from various donors may be cultured. The living cells derived from various donors are adhered and cultured in the cell culture kit as a whole, which makes it possible to provide a cell culture kit to conduct a test using cells derived from various donors.

Abstract: A cell culture device includes an isolator and an incubator. A connection unit is used to connect the isolator and the incubator, and is provided with: a flexible cell supply tube extending from the incubator to the isolator; and a tube support unit having a holding part holding the cell supply tube and a connection end part attached to the incubator. The tube support unit can be switched between a first configuration in which the tube support unit supports the cell supply tube such that the cell supply tube extends in a first direction and a second configuration in which the tube support unit holds the cell supply tube such that the cell supply tube extends in a second direction. The second configuration is switched to the first configuration by means of the restoring force of the tube support unit.