An apparatus is provided for holding down membrane elements in respective wells of a multiwell plate, which has, at its top side, respective openings of the respective wells. The apparatus has, at its upper region, a support structure having respective openings, and respective corresponding retention elements which extend downwards from the respective openings of the support structure, so that respective retention elements protrude into respective wells when the support structure has been placed onto the top side of the multiwell plate. A retention element has multiple webs which extend downwards from the support structure and the ends of which are connected to one another at a bottom side of the apparatus by means of a connection element. Furthermore, a retention element has multiple openings between the webs, which openings extend continuously from the support structure right up to the connection element and which openings furthermore extend continuously from the top side of the multiwell plate right up to the connection element when the support structure has been placed onto the top side of the multiwell plate.

Provided is a cell culture scaffold material having excellent cell adhesion. The cell culture scaffold material according to the present invention contains a peptide-conjugated polyvinyl alcohol derivative having a polyvinyl alcohol derivative portion and a peptide portion, and the peptide portion has a cyclic peptide skeleton.

A device for controlling apical flow to a cell culture includes an apical insert that defines at least one inlet channel extending from an inlet port to an apical feed port and at least one outlet channel extending from an apical effluent port to an outlet port. The apical insert includes a projecting portion configured to extend into a cell culture insert to a depth that is less than a depth of the cell culture insert, and a contact surface configured to maintain a spatial relationship between the projecting portion and the cell culture insert.

A spheroid cell culture article including: a frame having a chamber including: an opaque side wall surface; a top aperture; a gas-permeable, transparent bottom; and optionally a chamber annex surface and second bottom,
and at least a portion of the transparent bottom includes at least one concave arcuate surface, is disclosed. Methods of making and using the article are also disclosed.

The invention relates to a method for analyzing the effect of a gaseous medium on a biological test system using an extracellular metabolization system. The method consists of the following steps: a biological test sample is cultivated on a permeable carrier, the gaseous medium is guided over the surface of the biological test system in order to form an exposition atmosphere over the biological test system, the extracellular metabolization system is added to a conservation medium and the permeable carrier is brought into contact with a conservation medium that comprises the extracellular metabolization system below the permeable carrier, in such a manner that the extracellular metabolization system only passes through the permeable carrier and that the biological test system is not submerged by the conservation medium containing the extracellular metabolization system.

The present disclosure provides a biomimetic cell culture apparatus that mimics interactions among organs in a human body. The present disclosure includes a plurality of culture units for culturing cells, a conduit for connecting the plurality of culture units to each other to form a circulating path, a pump unit disposed on the conduit for forming a flow in culture medium such that the culture medium circulates through the plurality of culture units, and an agitating module for agitating the plurality of culture units.

Devices and methods for isolating and characterizing microbial cells from an environment are provided. The devices integrate sub-micron constrictions in a nanofluidic device with a standard microtiter plate format to facilitate the high throughput isolation, culturing, analysis, and screening of bacteria and other microbial cells in natural and man-made environments, particularly environments containing microbes adhered on particulate matter.

A cell culture well insert may include a frame defining a first open end, a second open end, and at least one support extending therebetween. The cell culture well insert may also include a fluid permeable mesh coupled to the frame and disposed across the second open end. The mesh may define pores that have an average pore size in a range from 10 micrometers to 100 micrometers.

A cell culture insert for use in culturing cells to promote the formation of spheroids and methods of using these spheroid-promoting cell culture inserts. The cell culture insert includes a porous membrane and one or more sidewalls that are non-adherent to cells and cause the cells in the insert to associate with each other and form spheroids.

A cell culture vessel including an accommodating part which is an inner space accommodating a cell culture support therein, a fixing member configured to fix the cell culture support to a lower surface of the accommodating part, wherein the fixing member includes a first adhesive layer attached to the lower surface of the accommodating part, a second adhesive layer attached to a lower surface of the cell culture support, and a support film interposed between the first adhesive layer and the second adhesive layer and configured to perform a support function, and an adhesive force between the second adhesive layer and the cell culture support is higher than an adhesive force between the first adhesive layer and the lower surface of the accommodating part.