The invention relates to a method for the formation of renal tubules by embedding individual renal cells into a synthetic hydrogel, which is based on polyethylene glycol as a component, and the culturing of the cells until tubule structures are formed. The culturing can be continued until the obtained tubule structures correspond in terms of size, structure, morphology and functionality to adult human renal tubules or are at least similar thereto.

The present invention relates to an insertable culture container and a kit for three-dimensional cell culture, and a three-dimensional cell co-culture method using the same, the insertable culture container for three-dimensional cell culture comprising: a cylindrical side wall having open upper and lower portions; at least one hook protruding outward from the upper side of the side wall; and at least one support protruding inward from the lower side of the side wall. The present invention is advantageous in that air required for a three-dimensional cell culture structure can be smoothly supplied since the cell is cultured at a position spaced apart from a bottom surface of the culture container, and an existing culture plate can be used without change due to the culture container configured as an insert type.

The invention relates to a cellular microcompartment comprising successively, organized around a lumen, at least one layer of pluripotent cells, an extracellular matrix layer and an outer hydrogel layer. The invention also relates to processes for preparing such cellular microcompartments.

The invention is directed to a modified polysaccharide hydrogel, comprising a low molecular weight alginate with a specific M/G ratio. The modified polysaccharide is modified with a specific peptide, preferably comprising a cell-adhesion peptide. The modified polysaccharide hydrogel may be used as a hydrogel for the growth of cultured meat preferably as a sacrificial biopolymer.

The present invention provides a cell culture having a cartilage-like tissue forming property, including a cell population in which the expression intensity of at least one cell surface marker selected from the group consisting of CD166, CD165, CD99, GD2, STRO-1, CD108, CD164, CD6, CD106, and CD107b is not higher than the threshold for each cell surface marker, and/or, the expression intensity of at least one cell surface marker selected from the group consisting of CD26, CD73, CD105, CD44, CD120a, CD201, EGFR, CD146, CD140a, and CD90 is not lower than the threshold for each cell surface marker.

[Problem] To provide a method for producing an artificial three-dimensional muscle tissue, said method enabling stable, efficient and easy production of a muscle tissue, and an artificial three-dimensional muscle tissue produced by this method. [Solution] A method for producing an artificial three-dimensional muscle tissue, said method comprising steps of (i) forming a three-dimensional muscle tissue precursor, which is configured from a first muscle tissue support, a second muscle tissue support and muscle cells, by linearly arranging the muscle cells on the first muscle tissue support in such a manner that the muscle cells are located close to the first muscle tissue support at one end of the line and close to the second muscle tissue support at the other end of the line, and (ii) culturing the three-dimensional muscle tissue precursor to give an artificial three-dimensional muscle tissue, and an artificial three-dimensional muscle tissue obtained by this method.

The invention provides a bioactive substance composition, a serum-free medium comprising the composition and the uses thereof. The bioactive substance composition is used for serum-free medium and/or composition and the preparation thereof; The serum-free medium and/or composition can be used for primary culture and secondary culture of cells and/or tissues. The cells are selected from any one or more of tendon and/or ligament derived cells, chondrocytes, meniscus stem cells, mesenchymal stem cells, skeleton stem cells, and muscle stem cells. The tissue is the musculoskeletal system tissue. The bioactive substance composition and/or serum-free medium and/or the composition can be used to prepare drugs for tissue and/or organ injury treatment; The tissue or organ injury is selected from the tissue or organ injury of the musculoskeletal system.

According to the present disclosure, there is provided a method for culturing factor-introduced cells, the method including culturing factor-introduced cells and recovering the factor-introduced cells and seeding at least part of the recovered cells in a medium for seeding. In addition, there is provided a method for culturing factor-introduced cells, the method including culturing factor-introduced cells and inducing the factor-introduced cells to somatic cells different from pluripotent stem cells without passaging.

Provided are methods of in vitro maturation of spermatogonium by culturing the spermatogonium in a three-dimensional methylcellulose culture system (MCS) in a culture medium which comprises an effective concentration of a factor selected from the group consisting of granulocyte macrophages-colony stimulating factor (GM-CSF), interleukin-1 alpha (IL-1alpha), interleukin-1 beta (IL-1beta) and interleukin-6 (IL-6), under conditions capable of differentiating the spermatogonium into at least meiotic and/or postmeiotic cells, thereby in vitro maturing the spermatogonium.

The present disclosure relates to an organ extracellular matrix-derived scaffold for culture and transplantation of an organoid and a method of preparing the same.