Ultrasonic devices comprise a housing comprising an ultrasonic surface, an ultrasonic transducer, and an ultrasonic horn to provide and focus energy from the ultrasonic transducer to the ultrasonic surface. Methods of removing trapped air bubbles from a cell culture container comprise positioning a cell culture container comprising air bubbles trapped in liquid within microcavity wells of the cell culture container at an ultrasonic surface of an ultrasonic device. Mechanical agitation is generated by the ultrasonic device and applied to the cell culture container to remove the trapped air bubbles from the microcavity wells. Methods of releasing cell aggregates from a cell culture container comprising positioning a cell culture container comprising cell aggregates in microcavity wells at an ultrasonic surface of an ultrasonic device. The cell aggregates are released from the microcavity wells by applying mechanical agitation from the ultrasonic device to a surface of the cell culture container.

A bioreactor has a container, an end plate, an agitator, a drive unit, and at least one field device arranged in the interior, field device electronics, a data transmission unit arranged on the end plate, and a motor head piece coupled in terms of energy to the drive unit. At least one communication unit is coupled in terms of signaling to the motor head piece and includes an adapter piece, having adapter electronics which are electrically connected to the field device electronics of the field device, and a communicator piece. The adapter piece and the communicator piece are separate components which can be coupled to one another, wherein the motor head piece is a separate component which can be coupled to the communication units.

Provided herein are systems and methods for thermally separating a flask and the base of an automatic flask stirring device. A thermal separator apparatus may be provided with a stand and a plurality of first standoffs. The stand may have a top surface configured to support a flask containing a substance to be stirred by a flask stirrer. The first standoffs may be located between the stand and a flask stirrer base, thereby creating a first air gap between the stand and the flask stirrer base. In some embodiments, the first air gap allows air to flow straight through the first air gap in a first direction.

A cell culture device is provided. A cell culture device according to an exemplary embodiment of the present invention includes: a main body comprising a culture space having one surface that is open; and a surface-modified sheet-type culture plate which is fixed to the main body to cover the opened one surface of the culture space, and thus forms a culture surface on which cells are cultured, and which forms the culture surface so that the cells can be attached to the culture surface.

Improved cell culture devices and related methods that overcome the limitations of prior devices and methods, by creating devices that can integrate a variety of novel attributes. These various attributes include the use of gas permeable material and medium volumes that exceed conventional devices as well as compartments that can facilitate the long term study of high density cultures with reduced disruption of the culture environment, the ability to study the migration of items of interest including substances such as chemokine, track the movement of cells, and monitor cell to cell interactions.

A system for processing samples from a body of fluid. The system includes one or more sample bottles for acquiring a sample from the body of fluid. Each sample bottle initially retains a pre-filling fluid. Each sample bottle includes a fluidic inlet port and a bottle outlet port. Each sample bottle has an inlet check valve coupled to the fluidic inlet port, the inlet check valve configured to allow fluid from the body of fluid into a sample bottle via the fluidic inlet port when the pressure difference between the body of fluid and fluid within the sample bottle reaches a threshold. The system further includes at least one pump, the bottle outlet port of each sample bottle selectively coupled to the at least one pump via a different control valve. The at least one pump is configured, in a first configuration, to remove prefilling fluid from each selected sample bottle such that, for each selected sample bottle, the pressure difference threshold is reached and a sample from the body of fluid is acquired.

Cells may be cultured by a method including the following steps: a first step of preparing a population of cell aggregates having a major axis of not more than 400 μm, and a second step of suspension culturing the population of cell aggregates obtained in the first step.

The present invention relates to a biocompatible device which comprises on its surface an adsorbed layer of a polymer P which is a copolymer of at least one macromonomer selected from an ester E of (meth)acrylic acid and polyethylene oxide or a polyethylene glycol (meth)acrylamide, at least one monomer M selected from alkyl (meth)acrylate, aryloxyalkyl (meth)acrylate, alkyl (meth)acrylamide or aryl (meth)acrylamide, and at least one cationic monomer C selected from cationic ethylenically unsaturated N-containing monomers. It further relates to a process for making a biocompatible device which comprises on its surface an adsorbed layer of the polymer P comprising the following steps: providing a biocompatible device, and applying to the surface of the biocompatible device a solution S of the polymer Pin a solvent L. It further relates to a solution S comprising the polymer P in the solvent L, where the solvent L comprises an alcohol; and to a process for cultivating cells, comprising the following steps: providing the biocompatible device and cultivating the cells in the supernatant medium above the surface of the biocompatible device.

A waste treatment, pyrolysis and gasification and concerns an apparatus for syngas bio-methanation include a unit for pyrolysis/gasification receiving organic material, the unit for pyrolysis/gasification generating syngas, comprising at least one membrane reactor inside a liquid bath comprising at least one bacteria population, the membrane reactor comprising at least one hollow fiber in contact with the liquid bath, around which a biofilm is formed and into which the syngas from the unit for pyrolysis/gasification flows, so as to convert the syngas into methane. A method for bio-methanation of syngas comprising a step of providing syngas from a unit for pyrolysis/gasification to a membrane reactor inside a liquid bath comprising at least one suitable bacteria population, the membrane reactor comprising at least one hollow fiber in contact with the liquid bath, around which a biofilm is formed and into which the output syngas of the unit for pyrolysis flows, so as to convert the syngas into methane.

A cell culture chamber device for growing cell cultures and tissues. The device includes: an enclosure containing a cell culture media, the enclosure being defined partly by a first end, a second end, and a connecting wall. The first end or a part or window thereof is substantially transparent, and the second end and/or the connecting wall, or a respective part or window thereof, is/are substantially transparent/translucent. The first end is configured to be optically aligned, at least for some period of time or periodically, with the second end and/or with the connecting wall so that light or another illumination or visualisation signal, transmitted through or by the second end and/or through or by the connecting wall into the enclosure is transmitted through the cell culture media and out through the first end to outside the enclosure, and e.g. to outside the cell culture chamber device.