There is provided a polymeric microsphere comprising a thermally responsive monomer crosslinked with a functional group monomer, wherein the functional group monomer comprises at least one of a carboxylic acid functional group or an amine functional group. The thermally responsive monomer is preferably N-isopropylacrylamide (NIPAM), and the microspheres preferably comprise a coating of polymerized catecholamines (e.g. DOPA). There is also provided a method of preparing the polymeric microsphere and uses of the polymeric microsphere in culturing, harvesting, or expanding stem cells or stromal cells. Preferably, the cells, e.g. hMSCs (human mesenchymal stem/stromal cells), are expanded or harvested in serum-free and xeno-free medium.

There is provided a polymeric microsphere comprising a thermally responsive monomer crosslinked with a functional group monomer, wherein the functional group monomer comprises at least one of a carboxylic acid functional group or an amine functional group. The thermally responsive monomer is preferably N-isopropylacrylamide (NIPAM), and the microspheres preferably comprise a coating of polymerized catecholamines (e.g. DOPA). There is also provided a method of preparing the polymeric microsphere and uses of the polymeric microsphere in culturing, harvesting, or expanding stem cells or stromal cells. Preferably, the cells, e.g. hMSCs (human mesenchymal stem/stromal cells), are expanded or harvested in serum-free and xeno-free medium.

Provided herein are microfluidic vascularized platforms and methods of using the platforms. Further provided herein are skin model systems comprising hydrogel layers of cells.

Provided herein are methods and systems for bio-printing of three-dimensional organs and organoids. Also provided herein are bio-printed three-dimensional organs and organoids for use in the generation and/or the assessment of immunological products and/or immune responses. Also provided herein are methods and system for bio-printing three-dimensional matrices.

A cell culture apparatus (1) of the present invention comprises: a culture vessel (2) in which a cell culture medium comprising at least one of culture components composed of a conjugate with a stimuli-responsive polymer is stored and cells are cultured in the medium; a stimulus-applying mechanism (4) that applies a predetermined stimulus to the conjugate so as to induce a predetermined change of the stimuli-responsive polymer in response to the stimulus; and, a separation mechanism (5) that separates at least a part of the medium components except for the conjugate from the cell culture medium, while leaving the conjugate in the cell culture medium, on the basis of a property change of the stimuli-responsive polymer.

The present invention provides for methods of isolating a stem cell or cell derived therefrom from a mixture of cells, for example, a mixture of adherent cells in culture. Cell isolation is achieved by the application of selective detachment forces.

The present invention provides for methods of isolating a stem cell or cell derived therefrom from a mixture of cells, for example, a mixture of adherent cells in culture. Cell isolation is achieved by the application of selective detachment forces.

The present invention relates to a cell culture support including a substrate and a thermoresponsive polymeric blend layer, wherein the polymeric blend layer includes at least one thermoresponsive polymer and at least one network forming adhesion promoter. The present invention further relates a method of making a cell culture complex including: providing a substrate; blending at least one thermoresponsive polymer and at least one network forming adhesion promoter to provide a polymeric blend; applying a thin film of said polymeric blend to the substrate to provide a polymeric blend layer on the substrate; curing the polymeric blend layer on the substrate to provide a cell culture support; and depositing cells onto said cell culture support, wherein the cells may optionally further include medium, to provide a cell culture complex.

A cell culture substrate includes: a first layer that includes a first gel in which gold nanoparticles dispersed; and a second layer that includes a second gel in which the gold nanoparticles are not present or are present in a lower concentration in comparison with the first layer.

The problem to be solved by the present invention is to provide a cultured cell sheet that expresses phenotypes of the chondroid tissue. The problems can be solved by producing the cultured cell sheet in which cells are cultured on a surface of a cell cultureware that is coated with a temperature responsive polymer having an upper or lower critical solution temperature ranging from 0 C. to 80 C. in water, including steps of: adjusting the temperature of the culture medium to a temperature below the lower critical solution temperature or above the upper critical solution temperature; bringing the cultured cell sheet in close contact with the carrier; and detaching the cultured cell sheet together with the carrier.