Abstract: The invention relates to devices, methods, kits, and compositions for in vitro generation of three-dimensional micro-tissues that are accurate models of heart, skeletal muscle, neuronal, and other tissues.

Abstract: The present invention relates to a device for cultivating cells, in particular tissue, comprising a carrier plate unit which has a central axis of rotation, at least one access opening arranged proximally to the axis of rotation, at least one cultivation chamber arranged distally to the axis of rotation, and at least one channel connecting the access opening to the cultivation chamber, and also a method for cultivating cells in a device according to the invention and a method for producing the device according to the invention.

Abstract: The present invention relates to a method for cultivating cells, in particular tissues, comprising a carrier plate unit, which has at least one access opening, at least one cultivation chamber, and at least one channel connecting the access opening to the cultivation chamber.

Abstract: The present invention is in the field of the cultivation of biological cells and tissues with organ-like function on a microphysiological scale and provides a method for the microphysiological co-cultivation of 3D organoid tissue and at least one 2D cell layer.

Abstract: The invention relates to the field of cultivating biological cells and tissues having an organ-like function on a microphysiological scale and provides a microphysiological reproduction of the choroid and the blood-retinal barrier as an in vitro test system.

Abstract: The invention relates to devices, methods, kits, and compositions for in vitro generation of three-dimensional micro-tissues that are accurate models of heart, skeletal muscle, neuronal, and other tissues.

Abstract: The invention relates to devices, methods, kits, and compositions for in vitro generation of three-dimensional micro-tissues that are accurate models of heart, skeletal muscle, neuronal, and other tissues.

Abstract: The present invention is in the field of the cultivation of biological cells and tissues with organ-like function on a microphysiological scale and provides a method for the microphysiological co-cultivation of 3D organoid tissue and at least one 2D cell layer.

Abstract: The invention relates to a microfluidic device which has at least one first culture chamber with cardiac muscular cells, at least one microfluidic channel, at least one pump (for example a micropump), and at least one detector, said detector being configured to detect an activity of the cardiac muscular cells contained in the culture chamber. The microfluidic device additionally contains at least one controller which is configured to control the at least one pump on the basis of the cardiac muscular cell activity detected by the at least one detector. The invention additionally relates to uses of the microfluidic device.

Abstract: The present invention relates to a device for cultivating cells, in particular tissue, comprising a carrier plate unit which has a central axis of rotation, at least one access opening arranged proximally to the axis of rotation, at least one cultivation chamber arranged distally to the axis of rotation, and at least one channel connecting the access opening to the cultivation chamber, and also a method for cultivating cells in a device according to the invention and a method for producing the device according to the invention.

Abstract: The present invention relates to a method for cultivating cells, in particular tissues, comprising a carrier plate unit, which has at least one access opening, at least one cultivation chamber, and at least one channel connecting the access opening to the cultivation chamber.

Abstract: The present disclosure provides a microfluidics device for culturing cells, such as cardiomyocytes or cardiomyocyte progenitors; and methods of culturing cells using the device. The device and culturing methods find use in drug screening methods, for methods of evaluating a drug under development, and for methods of predicting patient response to a given treatment regimen, which methods are also provided.

Abstract: Multi-organ cell culture systems and methods are provided. Aspects of the cell culture systems include at least two microfluidic cell culture units configured to culture a plurality of cells, one or more connectors configured to fluidly connect the microfluidic cell culture units to one another, a cell culture medium configured to support the growth of a plurality of different cell types, and a controller configured to move the cell culture medium at a specified volumetric flow rate between the microfluidic cell culture units. The subject systems and methods find use in a variety of applications, including in vitro evaluation of candidate agents for toxicity and efficacy, in vitro models of disease, and in vitro models for fundamental studies of biological systems.

Abstract: The invention relates to devices, methods, kits, and compositions for in vitro generation of three-dimensional micro-tissues that are accurate models of heart, skeletal muscle, neuronal, and other tissues.