Microfluidic device comprising at least one cell culture unit for forming, culturing, growing and/or maintaining a 3D tissue structure such as a 3D strip of cardiac tissue, wherein the at least one cell culture unit comprises: a respective culture chamber for culturing cells having a chamber outlet opening; and a cell supply channel arranged to guide a microfluidic flow of liquid holding cells between a channel inlet and a channel outlet, wherein the cell supply channel is provided with a flow inhibitor which is operable to selectively provide a flow inhibiting state or a flow permitting state depending on a fluid pressure at the flow inhibitor, wherein, in the flow inhibiting state, the flow inhibitor is configured to substantially inhibit liquid flow between the cell supply channel and the culture chamber, wherein, in the flow permitting state, the flow inhibitor is configured to permit such liquid flow such that the cell supply channel is in liquid communication with the culture chamber to supply the culture chamber with cells, wherein the culture chamber is provided with at least two mutually spaced apart elastic support structures which extend in the culture chamber and which are configured for elastically supporting a tissue formed in the culture chamber, in particular a cultured 3D tissue formed from the cells, wherein the elastic support structures are elastically deformable, in particular flexible, in particular to vary a mutual distance of said support structures under influence of a varying contraction force between said support structures.

A system and method for conditioning a tissue are provided. The system includes a substrate, a plurality of microwells formed in the substrate, and a microsphere associated with each of the plurality of microwells. The system also includes a pair of flexible pillars within each of the plurality of microwells. Each flexible pillar includes a first end bonded to a respective microwell and at least one flexible pillar has a second end bonded to the microsphere. The flexible pillars are configured to deflect when exposed to a magnetic field to controllably stretch microtissue spanning the flexible pillars.

A full-function artificial organ fitting body comprises a cortex layer and an organ body tissue area. The organ body tissue area comprises a growth area, a differentiation area, a docking area, a branch arterial system, a branch nervous system and a branch venous system. The branch arterial system, the branch nervous system and the branch venous system are distributed in the differentiation area and form a main body three-dimensional skeleton structure with the outer growth area and the middle docking area.

The invention provides articles of manufacture comprising biocompatible nanostructures comprising nanotubes and nanopores for, e.g., organ, tissue and/or cell growth, e.g., for bone, kidney or liver growth, and uses thereof, e.g., for in vitro testing, in vivo implants, including their use in making and using artificial organs, and related therapeutics. The invention provides lock-in nanostructures comprising a plurality of nanopores or nanotubes, wherein the nanopore or nanotube entrance has a smaller diameter or size than the rest (the interior) of the nanopore or nanotube. The invention also provides dual structured biomaterial comprising micro- or macro-pores and nanopores. The invention provides biomaterials having a surface comprising a plurality of enlarged diameter nanopores and/or nanotubes.

The present subject matter provides a microfluidic device that enables the precise and repeatable three dimensional and compartmentalized coculture of muscle cells and neuronal cells. Related apparatus, systems, techniques, and articles are also described.

Systems and methods are disclosed herein for use in transducing, activating, and otherwise treating cells. Cells are introduced into an inner layer of a multi-layered stack that defines at least one flow chamber and a plurality of cell entrainment regions. Vertical flow through the stack entrains the cells in the cell entrainment regions along with genetic information introduction agents or other additives, before the cells are washed using a reverse vertical flow and are collected from the device.

Embodiments for coating a bioreactor with a reagent are described. The embodiments may provide for changing flow rates, direction of flow, and/or bioreactor rotation to enhance the coating of the bioreactor prior to growing cells in the bioreactor.

The invention relates to a method for detecting organisms in a liquid sample, comprising the provision of a capture area including particles in a liquid medium and subjected to a hydrodynamic flow, wherein the organisms to be detected are capable of binding to these particles, the method comprising the steps of: (a) circulating the sample through the capture area; (b) circulating a growth medium through the capture area; and (c) determining the presence, nature or concentration of organisms in the capture area; said particles being retained in the capture area as a fluidized bed for at least one part of these steps.

The invention also relates to a system for implementing this method.

An assembly and method to precisely and concurrently control the concentration, release, and depletion of chemical and biochemical species in localized regions in a three-dimensional volume of material using spatially patterned light. The system includes a container for holding a material comprising photo-responsive substance; the container is mounted to a motorized rotation stage that rotates the container along the z-axis at a predetermined rate; and a projector configured to project radiations at predefined wavelengths along an r-axis into the container while the container is rotating, wherein the radiations from multiple angles intersect to form localized photoreactive regions within a volume of the material.

Systems and methods are provided for growing algae and/or other microorganisms in a controlled environment while reducing or minimizing the amount of energy required for maintaining desired conditions in the growth medium. The systems can be based on a photobioreactor having a “tube-in-tube structure”, where an outer cylindrical tube contains a heat regulation fluid that surrounds one or more inner cylinders that contain microorganisms in growth media. The heat regulation fluid in the outer cylinder, as well as the outer cylinder itself, can assist with regulating the temperature of the growth media in the inner cylinder(s).