The present disclosure provides a culture device for enumerating colonies of sulfate-reducing microorganisms. The device includes a body having a waterproof base, a waterproof coversheet attached to the base, and a growth compartment disposed therebetween. The growth compartment has a perimeter and an opening. A portion of the perimeter is defined by a waterproof seal. The portion can include >50% of the perimeter. Disposed in the growth compartment are a dry cold water-soluble gelling agent, a dry culture medium selected to facilitate growth of a sulfate-reducing bacterium or indicator reagent for detecting hydrogen sulfide production by a sulfate-reducing bacterium, and a dry first oxygen-scavenging reagent.

An array device including a base having wells, a cover positioned over the base with a gap from the base such that openings of the wells are covered by the cover with the gap in between, an injection port communicating with the gap, a discharge port communicating with the gap and positioned apart from the injection port, and a waste liquid vessel which collects liquid that flows from the gap via the discharge port and is positioned at a level different from the gap forming a channel. The discharge port is placed to discharge a surplus aqueous solution outside the wells from the discharge port by an oleaginous sealing liquid to be delivered from the injection port.

A sample loading cartridge (1) for a microfluidic device comprises a cartridge body (10) with a sample reservoir (20) configured to house a volume of a liquid sample (3) and a sample port (30) in connection with the sample reservoir (20). The cartridge (1) also comprises an output channel (40) extending from the sample reservoir (20) and a feedback channel (50) connected to the sample reservoir (20) and to the sample port (30). The cartridge body (10) comprises a detection portion (60) aligned with the feedback channel (50) to enable detection of any sample (3) in the feedback channel (50). The flow resistance of the feedback channel (50) is lower than the flow resistance of the output channel (40) to cause liquid sample (3) received in the sample port (30) to enter the feedback channel (50) with substantially no liquid sample (3) entering the output channel (40).

Methods for laser-assisted repositioning of a micro-object and for culturing an attachment-dependent biological cell within a microfluidic device are described herein. Laser illumination is used to controllably create a bubble which repositions the micro-object. Further, methods of culturing an attachment-dependent biological cell are described, where the methods may include laser-assisted repositioning.

There is provided a method for easily determining an undifferentiated state of pluripotent stem cells without relying on the judgment of a skilled technician. The method includes: a step of evaluating an undifferentiated state of pluripotent stem cells based on a time-dependent change in a variation value of an extracellular metabolite contained in a culture medium in which the pluripotent stem cells are cultured, wherein the extracellular metabolite is at least one selected from a group consisting of L-glutamic acid, L-alanine and ammonia.

A container system includes a flexible bag bounding a chamber. A probe port includes an elongated tubular member having an interior surface bounding a first passageway and extending between a first end and an opposing second end, the first passageway being closed at the first end and open at the second end; and a flange encircling and radially outwardly projecting from the tubular member at or toward the second end thereof, the flange being secured to the flexible bag so that the first end of the elongated tubular member projects into the chamber of the flexible bag while the open second end of the elongated tubular member is accessible from outside of the flexible bag. A probe is received within the first passageway of the probe port.

Provided herein are a device and a method for preparation of immobilized proteins, enzymes or cells on a carrier to achieve the industrial batch production of the immobilized proteins, enzymes or cells.

A device and method for lysing biological species present in a fluid includes implementing a rough surface against which the objects to be lysed are crushed by a shearing motion. A device for mechanically lysing biological species has a first and second wall mounted movable relative to each other, between an initial position in which the walls are separated from each other, and a lysing position in which the first wall presses against the second wall. The first and second walls also are mounted shearingly movable relative to each other in the lysing position. At least one of the first or second walls has a rough bearing surface against the other wall and has a mean surface roughness parameter Ra of between 0.2 μm and 10 μm, and preferably between 0.2 μm and 3 μm.

An electroporation device with a volume of varying cross sectional area that as a fast assay device for determining the optimal conditions for plasma membrane electroporation.

The disclosure relates to methods, systems and compositions for physically manipulating a muscle tissue culture either mechanically, or manually, or both. Specifically, the disclosure relates to systems and methods of physically manipulating, either mechanically or manually, a resilient container of bioprinted tissue culture having non-random three dimensional cell structure by elongation, compression, torque and shear of the tissue culture.