A method of obtaining 3D cell structures including differentiated human hepatic cells. The method includes: a first step of culturing stem cell-derived or immortalized human hepatic progenitors in a non-adherent culture vessel, preferably a low or ultra-low attachment culture vessel; a second step of transferring the stem cell-derived or immortalized human hepatic progenitors to a culture medium including methacrylated gelatin (GelMa), thereby embedding the stem cell-derived or immortalized human hepatic progenitors in a GelMa matrix; and a third step of covering the GelMa matrix with culture medium and culturing the stem cell-derived or immortalized human hepatic progenitors embedded in the GelMa matrix, thereby obtaining 3D cell structures including differentiated human hepatic cells. Also, methods for engineering an artificial liver model or an artificial liver organ, and for assessing in vitro the metabolism, toxicity and/or therapeutic effects of a compound.

A method of efficiently recovering a large amount of exosomes from mesenchymal stem cells is provided. The method includes: a three dimensional culture step of three dimensionally culturing mesenchymal stem cells in a medium containing sugar by using a nonwoven fabric as a scaffold; a post-plateau culture step of further culturing for a certain period of time after the amount of the sugar consumed by the mesenchymal stem cells reaches a plateau; and an exosome recovery step of recovering exosomes from the mesenchymal stem cells. The mesenchymal stem cells are adipose-derived mesenchymal stem cells.

The invention concerns novel methods and materials for preparing extracellular matrix (ECM) powder pre-gel and gel solutions, for example for use in organoid culture. The ECM gels demonstrate excellent physiological and mechanical properties while having the proteomic signature of endoderm tissue with specific enrichment of key ECM proteins relevant to organoid formation.

Engineered tissue models based on three-dimensional (3D) scaffolds, also referred to herein as tissue-engineered 3D models, can be used as in vitro diagnostic and drug screening tools for predicting, preventing and/or treating cancer metastases.

The present invention relates to methods for reprogramming somatic cells into pluripotent stem cell-like cells. Such cells may express pluripotency inducing genes including Oct4, Nanog and Sox2 without introducing exogeneous genes, proteins, or chemicals. The discovery that the inhibition of mechanosensitive and stretch-activated ion channels in somatic cells specifically activates pluripotency inducing factor genes inspired the cell reprogramming culture methods in which somatic cells were incubated with the inhibitor, GsMTX4, against mechanosensitive and stretch-activated ion channels, cultured on the soft hydrogel surface, or treated with cholesterol depletion substance, methyl-beta-cyclodextrin (MβCD). Described methods produce pluripotent stem cell-like cells and subsequently re-differentiated cells, which include adipocytes, osteocytes, neuronal cells. Methods may be combined to increase the efficiency of the somatic cell reprogramming A somatic cell reprogramming kit was also created with tissue culture dishes casted with hydrogel (dehydrated) and MβCD.

Disclosed herein is a method for covalent immobilization of molecular compounds on a substrate surface, comprising the steps: Providing a substrate surface; Treating the substrate surface with a plasma at atmospheric pressure, thereby generating an activated surface site; Exposing at least the activated surface site, or some fraction of the activated surface site, to molecular compounds, thereby establishing a covalent bond between the molecular compounds and the substrate surface.

A cell culture substrate having a high cell-adhesion portion and a low cell-adhesion portion, wherein; an adhesiveness to a cell of the high cell-adhesion portion and an adhesiveness to a cell of the low cell-adhesion portion are different from each other, the adhesiveness to the cell of the high cell-adhesion portion to cells is higher than the adhesiveness of the low cell-adhesion portion to the cell; and the high cell-adhesion portion has a cell adhesion layer containing two or more kinds of cell adhesion substances on the surface.

Compositions, devices and methods are described for improving adhesion, attachment, and/or differentiation of cells in a microfluidic device or chip. In one embodiment, one or more ECM proteins are covalently coupled to the surface of a microchannel of a microfluidic device. The microfluidic devices can be stored or used immediately for culture and/or support of living cells such as mammalian cells, and/or for simulating a function of a tissue, e.g., a liver tissue, muscle tissue, etc. Extended adhesion and viability with sustained function over time is observed.

The present disclosure provides a method of fabricating curvature-defined (C-D) or shape-defined (S-D) concave and convex polydimethylsiloxane (PDMS) surfaces and a method of fabricating C-D or S-D convex and concave gel surfaces for use in cell and tissue culturing and in other surface and interface applications, and provides a method of using C-D or S-D convex and concave surfaces with varying curvatures to direct cell attachment, spreading, and migration.

Disclosed herein are neural extracellular vesicles (EVs) and methods of using these EVs in the treatment of spinal cord injury, stroke, and traumatic brain injury and neurodegenerative disease.