Abstract: A method for three-dimensional reproduction of a biological tissue in the framework of tissue engineering. A substrate is provided and primary cells of a first cell type are deposited on the substrate. A first precursor of a substance adhering the cells is arranged on at least a selection of the primary cells of the first cell type. A second precursor of the substance adhering the cells is arranged in a locally targeted manner on the selection of primary cells of the first cell type according to a structure formed by cells of the first cell type in the tissue to be reproduced. The first precursor and the second precursor react with each other to form the substance adhering the cells, which substance adheres the selection of the primary cells of the first cell type according to the structure formed by the cells of the first cell type in the tissue to be reproduced.

Abstract: The present invention relates to a method for producing a structure modeled on a biological tissue. The invention also relates to a structure which can be produced using the method according to the invention. According to an embodiment of the invention, a precursor of a biopolymer is locally irradiated with electromagnetic radiation in a targeted manner, wherein the irradiation, in particular the selection of the areas to be irradiated, is effected according to data which describe a structural construction at least components of the extracellular matrix of the biological tissue. In this case, the electromagnetic radiation is such that two-photon or multi-photon absorption takes place in the irradiated areas of the precursor and results in the precursor being polymerized to form the biopolymer in the irradiated areas, with the result being that the precursor is at least partially solidified there.

Abstract: The present invention relates to a method for producing a structure modeled on a biological tissue. The invention also relates to a structure which can be produced using the method according to the invention. According to an embodiment of the invention, a precursor of a biopolymer is locally irradiated with electromagnetic radiation in a targeted manner, wherein the irradiation, in particular the selection of the areas to be irradiated, is effected according to data which describe a structural construction at least components of the extracellular matrix of the biological tissue. In this case, the electromagnetic radiation is such that two-photon or multi-photon absorption takes place in the irradiated areas of the precursor and results in the precursor being polymerized to form the biopolymer in the irradiated areas, with the result being that the precursor is at least partially solidified there.

Abstract: The invention relates to a hybrid three-dimensional sensor array, in particular for measuring biological cell assemblies. The sensor array has a plurality of microstructured sensor plates, each having one carrier section on which a plurality of sensor needles are arranged in a comb-like manner, which carry a plurality of electrode surfaces. Furthermore, a plurality of spacer elements are provided, which are fastened between the sensor plates so that both the carrier sections and the sensor needles of adjacent sensor plates are at a distance from each other. The invention further relates to a measuring assembly for measuring electrical activities of biological cell assemblies using such a sensor array.

Abstract: The present invention relates to a microbioreactor comprising a sample support (7) for holding cells; a bypass (3) with a capillary opening for feeding test reagent and/or for aeration and ventilation of the microbioreactor; a pump module (5) for perfusion of the microbioreactor with test reagent and/or gas feeding and purging of the microbioreactor; a transparent viewing window (2); and fluid channels (4) that form a circuit. The invention further relates to a bioreactor-microtiter plate comprising a plurality of such microbioreactors.

Abstract: The invention relates to a partially active microfluidic system for cell cultivation comprising a multiwell system (4) with multiple wells (17) and cavities formed therein that hold cells. Each cavity (11) is formed by at least one inlay (3) comprising an opening (1) that does not open up directly into the cavity (11), but rather into a space (17) surrounding the cavity, wherein the medium present in the surrounding space communicates with the medium contained in the cavity (11) by way of a sieve structure in the inlay. The invention is suitable in particular for 3D cell cultivation.