The present invention relates to a method and system for introducing one or more exogenous substances into an immune cell. The method comprises the steps of: providing a membrane having a plurality of pores configured to allow the immune cell to pass through, wherein the plurality of pores has an average pore diameter which is no less than an average diameter of the immune cell nucleus and no more than an average diameter of the immune cell, passing a fluid containing the immune cell and the on e or more exogenous substances through the plurality of pores to induce a mechanical stress to the immune cell and facilitate introduction of the one or more exogenous substances into the immune cell, and recirculating the fluid containing the immune cell and the one or more exogenous substances such that the same immune cell passes through the membrane more than once. In some embodiments, the immune cell is T-cells and the exogenous substance is mRNA.

Provided herein are filter cake-based systems and methods for cultivating cells and cell biomass therefrom. Provided herein is a system for cultivating cells and cell biomass comprising a filter chamber comprising at least one inlet and at least one outlet, at least one filter support located within the filter chamber, and a filter cake located on the filter support, wherein the filter cake comprises at least one filter aid and a plurality of cells. Provided herein is a method for optimizing the cultivation of cells and cell biomass, comprising providing a filter support, adding at least one filter aid to the filter support, adding a plurality of cells to the filter aid, wherein the cells and the filter aid together comprise a filter cake, growing the cells into a cell biomass in the filter cake, wherein the filter cake is at least partially compressible.

Provided are new strategies, methods and systems, described herein as vasoactive intestinal peptide (VIP)-assisted air-liquid-interface (ALI) culture, to significantly increase the number of enteroendocrine (EEC) and enterochromaffin (EC) cells over the traditional submerged culture, while at the same time maintaining a high barrier integrity of monolayers. The new strategies, methods and systems overcome the limitations of the existing EEC enrichment methods by maintaining high cell viability and barrier integrity and without requiring complicated procedures of cocultures or genetic engineering/induction. The created EEC-enriched, contiguous monolayer platform acts as a robust analytical tool to enable functional studies of hormone secretion from EEC cells with high signal background ratio and repeatability.

Described herein is a microfluidic chip comprising a first channel in fluid communication with an adjacent second channel through a opening, wherein the height of the first channel and the second channel are chosen to generate sufficient surface tension at the opening such that a liquid injected into the first channel or the second channel is substantially confined within the first channel or the second channel, respectively, or that flow of the liquid therebetween is controlled, the surface tension producing a non-physical microfluidic barrier that limits or selectively controls passage of the liquid. Also described are in vitro microphysiological systems that use such microfluidic chips in modeling the structure and functions of human organs, such as a blood-brain barrier, and studying in vivo-like physiological responses of such organs to various investigative or therapeutic agents.

A packed-bed bioreactor system is provided, the system including a cell culture vessel having a first end, a second end, and a reservoir between the first and second ends; and a cell culture matrix disposed in the reservoir. The cell culture matrix includes a structurally defined substrate with a plurality of interwoven fibers having surfaces for adhering cells thereto. The substrate is disposed within the reservoir in a wound configuration creating a plurality of layers of substrate in the wound configuration, and none of the plurality of layers of substrate are separated by a spacer material.

Disclosed is an in vitro exposure system that may radiate a uniform field having a constant wavefront to an experimental cell container and expose each cell container to a same electromagnetic field.

The present invention relates to a filtration unit with a filtration membrane, nutritive cardboard disc and, if necessary, a support structure, wherein the nutritive cardboard disc and/or the support structure comprises a solid, water-soluble nutrient medium and a water-soluble and/or water-swellable polymer, a method for producing the filtration unit, a method for detecting microorganisms in a fluid, wherein the filtration unit is used, and the use of the filtration unit for detecting microorganisms in a fluid.

The present invention relates to a Disposable Bioprocess System consisting of a Single-Use-Bioreactor, a Single-Use-Pump and a single-use micro-organism retention filter. Combined most suitable for cultivation of suspended micro-organisms in a liquid media at high micro-organism concentration in a perfusion mode continuous process for expression of biological material. The inlet port of the liquid Single-Use-Pump connects via a valve to the broth reservoir of the Single-Use-Bioreactor through a liquid conveying port. The outlet port of the liquid pumping Single-Use-Pump connects via a valve to a micro-organism retention filter. And a method for operating said sterile Disposable Bioprocess System in perfusion mode for continuously processing.

The invention relates to a long term cell culturing method and a cell culturing apparatus and kit that employ a porous polyimide film. The invention further relates to a cell cryopreservation method and kit employing the porous polyimide film.

This disclosure relates to methods of growing cells within a hydrogel scaffold and pressurizing the hydrogel and cells to induce the cells to stretch and differentiation. The disclosed method can include coating a substrate of a bioreactor with a hydrogel and seeding cells onto the hydrogel and/or the substrate. The disclosed method can further include growing the seeded cells into a cell mass and pressurizing the cell mass and the hydrogel within the bioreactor. Pressurizing the cell mass and the hydrogel induces the cell mass and hydrogel to mechanically stretch, thereby inducing hypertrophy and cell alignment.