Herein is reported a method for the co-cultivation of single deposited B-cells, which can be of any source, with EL-4 B5 feeder cells in a suitable co-cultivation medium. In the herein reported methods the EL-4 B5 cells have been irradiated with a dose of less than 40 Gy, preferably 9.5 Gy or less. Thereby the EL-4 B5 cells have a higher viability and maintain the ability to divide in cultivation at doses less than 6 Gy.

The present invention relates to a method for preparing a growth-factors containing platelet releasate from a fluid mammalian platelet concentrate, comprising the consecutive steps of subjecting the platelet concentrate to a pathogen reduction step to disrupt non-enveloped viruses; subjecting the platelet concentrate to an activation step to cause the platelets to release growth factors; recovering a fibrinogen depleted fluid platelet releasate; subjecting the fibrinogen depleted fluid platelet releasate to a second pathogen concentration reduction step to disrupt enveloped viruses; subjecting the platelet releasate to sterile filtering and recovering a filtrate liquid containing the growth factors.

The platelet releasate obtained with the method of the present invention may be used as a therapeutic agent to enhance the proliferation of multi lineage cells in regenerative medicine and in the management of non healing wounds and resistant ulcers. The second indication is as a substitute to fetal bovine serum in in cell culture media.

Described herein are a system, device, methods and compositions related to generating 3-dimensional cardiac tissues. Also described herein are a system, device, and methods of maturing 3-dimensional cardiac tissues and maintaining their viability in culture.

Provided is an electroactive structure and method for growing isolated differentiable cells comprising a three dimensional matrix of fibers formed of a biocompatible synthetic piezoelectric polymeric material, wherein the matrix of fibers is seeded with the isolated differentiable cells and forms a supporting scaffold for growing the isolated differentiable cells, and wherein the matrix of fibers stimulates differentiation of the isolated differentiable cells into a mature cell phenotype on the structure.

The present invention relates to a method of inducing differentiation into a 3D dopaminergic midbrain organoid using a specific electromagnetic wave. It was specifically identified that the method makes it possible to remarkably improve production efficiency of a dopaminergic neuronal 3D-differentiated organoid, from which symptoms of Parkinson's disease can be effectively alleviated. Thus, it is anticipated that the present invention is capable of making a more fundamental approach and achieving targeted therapies in the treatment of a cranial nerve disease.

The present invention relates to apparatuses for use in electrophoretic separation of macromolecules and/or cells.

A bioelectronic device for regulating stem cell differentiation, a method for differentiating stem cells using the same, and a method for manufacturing the bioelectronic device. According to the present invention, it is possible to effectively control the differentiation of stem cells at a single-cell level, and to simultaneously perform a free radical inhibition function.

A method for in vitro activation and/or expansion of immune cells is provided, including the steps of: a) providing magnetic particles having multi-protrusive surface modified with at least one type of immuno-inducing substance, in which each magnetic particle includes a copolymer core, a polymer layer, a magnetic substance layer, and a silicon-based layer from the inside to the outside; b) providing a cell solution including at least one type of immune cell in the cell solution; and c) bringing the magnetic particles in contact with the cell solution, in which the at least one type of immuno-inducing substance on the surface of the magnetic particle activates and/or expands the at least one type of immune cell in the cell solution.

The present invention relates to a method for transdifferentiating cells. The present invention provides a method for transdifferentiating fibroblasts into chondrocytes, comprising: forming a micromass of fibroblasts by culturing fibroblasts in a high density; and applying an electrical stimulation such as a current or magnetic field to the micromass of fibroblasts while culturing the micromass of fibroblasts in a culture medium not containing growth factors.

The present disclosure provides a planar microelectronic human blood brain barrier stack used to model drug effects and transport across the brain capillary endothelial barrier to neurons. In one embodiment the stack is comprised of a carrier substrate, electrode arrays, astrocytes, extracellular matrix and brain capillary endothelial cells.