The present disclosure relates to a micropatterned substrate that combines Si and TiB.sub.2, promoting preferential and selective cell growth behavior via substrate-mediated protein adsorption. The combination of Si and TiB.sub.2, differing in material stiffness, hardness, roughness, wettability and surface charges, is amenable to microfabrication processes and supports extended 2D and 3D cell culture. While versatile in the variety of customizable geometric patterns, the micropatterned substrate is a particularly appropriate platform for viable tissue culture.

The processing apparatus 200 of the present disclosure includes: a laser irradiation unit 21 capable of applying a laser to the photothermal conversion layer 13 of the cell culture tool 100 including the cell culture base layer 11 and the photothermal conversion layer 13; and a control unit 22 for controlling the laser irradiation unit 21. The control unit 22 includes a setting section 221 and an irradiation control section 222. The setting section 221 sets an irradiation region to be irradiated with the laser in the cell culture tool 100. The irradiation control section 222 controls the laser irradiation unit 21 based on the irradiation region such that the laser irradiation unit 21 applies the laser to a corresponding region of the photothermal conversion layer 13.

The present invention relates to a microfluidic device (1), preferably for producing a three-dimensional cell culture, having at least one chamber (2), and a fluid channel (3) which flows through at least part of the chamber (2) in order to provide a fluid stream which flows through the chamber (2) preferably continuously, wherein the chamber (2) is connected to a loading opening (4) and via the loading opening (4) can be loaded with hydrogel up to a desired fill level, characterized in that the chamber (2) comprises a main chamber (5) and a secondary chamber (6) connected to the main chamber (5), wherein, when the chamber (2) is being loaded with hydrogel up to the desired fill level, the secondary chamber is at least partially filled with hydrogel backed up from the main chamber (5).

A biocontainer film enhanced with an abrasion resistant or “cut-proof” substrate. Such substrates can be combined with current biocontainer materials, via various techniques of embedding, coextrusion or laminating, to maintain the cleanliness and low extractables already validated for biotech manufacturing. The substrate of choice may be constructed from materials known to be more resistant to abrasion and sharp razor type cuts or from materials oriented in such a way to prevent puncture to occur. The new substrate must also be flexible to allow for typical folding as demonstrated by current packaging practices. The new substrate may be constructed from materials other than polymers such as metal, glass or carbon or in combination with polymers. A non-constrained pressure test is also disclosed.

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.

Embodiments described herein generally provide for the expansion of cells in a cell expansion system using an active promotion of a coating agent(s) to a cell growth surface. A coating agent may be applied to a surface, such as the cell growth surface of a hollow fiber, by controlling the movement of a fluid in which a coating agent is suspended. Using ultrafiltration, the fluid may be pushed through the pores of a hollow fiber from a first side, e.g., an intracapillary (IC) side, of the hollow fiber to a second side, e.g., an extracapillary (EC) side, while the coating agent is actively promoted to the surface of the hollow fiber. In so doing, the coating agent may be hydrostatically deposited onto a wall, e.g., inner wall, of the hollow fiber.

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.

Embodiments described herein generally provide for the expansion of cells in a cell expansion system using an active promotion of a coating agent(s) to a cell growth surface in some embodiments. A coating agent may be applied to a surface, such as the cell growth surface of a hollow fiber in a bioreactor, by controlling the movement of a fluid in which a coating agent is suspended, by changing flow rates, by changing flow directions, by rotation of the bioreactor, and/or combinations thereof.

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 invention relates to peripheral blood mononuclear cell (PBMC) monolayers or bone-marrow cell monolayers and methods for its culture and corresponding uses of said monolayers. The present invention also relates, in some aspects, to screening methods comprising the PBMC monolayer or bone-marrow cell monolayer of the invention for determination of response or lack of response of a disease to a therapeutic agent and/or drug screening methods. In some aspects, the invention further relates to methods for diagnosing a disease or predisposition to a disease in a PBMC donor or bone-marrow cell donor comprising the PBMCs/bone-marrow cells cultured according to the method of the invention and/or to methods for determining whether the disease is likely to respond or is responsive to treatment with a therapeutic agent.