According to the present invention, an initial-stage test apparatus-culturing condition (parameter set) is determined (22) on the basis of a manual culturing condition (26) for a specific cell. Multiple apparatus-culturing tests (20) are run in accordance with multiple test apparatus-culturing conditions, including the initial-stage test apparatus-culturing condition. A test apparatus-culturing condition at the time point when the result of an apparatus-culturing test satisfies requirement specifications is set (40) in a culturing apparatus as a setting apparatus-culturing condition, and the culturing apparatus is set up by using said setting apparatus-culturing condition.

An assembly includes a housing with opposite first and second layers. The first and second layers are spaced apart to define a confined interior space. A semi-permeable membrane is attached to the first layer, the semi-permeable membrane covering a porous area portion of the first layer. An outlet port and an inlet port are in fluid communication with the interior space. The assembly includes a first circulator for circulating a first fluid between the outlet port and the inlet port, and a second circulator for circulating a second fluid along an exterior surface of the semi-permeable membrane. The second circulator includes a fluid duct attached to or integrated within the housing. The fluid duct is isolated from the interior space and is porous to provide fluid access to an exterior surface of the semi-permeable membrane. The semi-permeable membrane forms a barrier allowing exchange of compounds across the membrane.

An algae cultivation system may include: a plurality of panels within a cultivation container, positioned along a first axis perpendicular to the gravitational force, wherein a cultivation volume is created between each pair of panels, and wherein the cultivation volumes are fluidly coupled so as to allow horizontal flow therebetween along the first axis; at least one first sparger, to distribute a first fluid into the container at a first operating flow rate; at least one second sparger, to distribute a second fluid into the container at a second operating flow rate; and at least one controller, to control the first operating flow rate and the second operating flow rate. The first operating flow rate may be adapted to allow turbulent mixing the algae in the cultivation container, and the second operating flow rate may be adapted to allow assimilation of materials in a liquid in the cultivation container.

A storage assembly for storing a plurality of specimens includes a frame, a plurality of modular storage units for perfusion and/or incubation of one or more specimens removably coupled to the frame, a sample transfer apparatus configured to retrieve a specimen holder from a chosen modular storage unit of the plurality of modular storage units, and a control unit communicatively coupled to the sample transfer apparatus. The control unit is configured to cause the sample transfer apparatus to retrieve a specimen from a modular storage unit of the plurality of modular storage units and deliver the specimen to a delivery position.

To continue a series of cell treatments even in a case where a treatment has become impossible in any isolator, a cell treatment system is provided with at least two isolators that perform different treatments, such that a sequential series of cell treatments is performed in each of the isolators. The cell treatment system is provided with a first isolator that performs a first treatment, a second isolator that performs a second treatment different from the first treatment, and a common isolator capable of performing the first treatment and the second treatment.

This new artificial intelligence application identifies micro-organisms, matter and contaminates from the bottom of lakes, rivers, harbors, streams and any other large bodies of water utilizing conveyor belts with and without embedded microscope slides, watertight containers, high definition lenses, drones, robots, artificial intelligence and machine learning algorithms. The AI application can be used below and above the surface of water. The AI command center utilizes a gorilla glass panel to manipulate by finger or hand to be viewed clearly by the human eye the matter, microbes and contaminates on the glass before and after they have been analyzed by the algorithms and servers.

A culture device by which microalgae can be satisfactorily cultured using a simple structure while suppressing an increase in energy consumption, and a culture method. A main body of this culture device comprises an accommodation part which accommodates contents and to which gas is supplied. The inner wall faces of the accommodation part are joined together to form a joined part which extends along the gas supply direction. A guide part and a circulation part, which are adjacent to each other across the joined part, are each along the extending direction of the joined part and communicated with each other via a guide part inlet and a guide part outlet. A gas supply port enables gas supply toward the guide part.

A bioreactor includes a reservoir container for holding a liquid medium, a duct providing a flowpath in a generally vertical direction upward from the reservoir container, a plurality of fiber assemblies located within the duct, a top of which is higher than a top of the plurality of fiber assemblies, and a circulation system. The upper end of the duct comprises an overflow wall surrounded by a moat, a bottom of which is lower than a top of the overflow wall. The upper end of the duct and moat contact a pocket region that is bounded by a structure that is connected to the duct and that is isolated from fluid communication with an exterior of the pocket region. The liquid medium flows over the overflow wall within the pocket region, contacts gas in the pocket region, overflows into the moat and is removed therefrom by the circulation system.

A modular incubator includes a housing including one or more fastening mechanisms for attachment to a workstation frame, a platform located at the housing and defining a sample placement area, and a chamber wall structure coupled to the platform. The chamber wall structure is pivotable between a closed position against the platform to form a sample chamber and an open position in which a front end of the chamber wall structure is spaced apart from the platform to allow access to the sample placement area. The modular incubator further includes a lid coupled to and openable from the chamber wall structure to expose at least a portion of the chamber wall structure for viewing.

The present invention relates to systems and methods for tissue processing and analysis. Tissue chambers are configured to allow single-container chemical processing, imaging, and wax embedding of tissue samples in a single container without manipulation between steps. Tissue chambers with features to support the tissue sample and allow fluid flow between the tissue sample and the tissue chamber surface are disclosed. The features may be index matched to sample structures of interest or dissolvable in clearing solution to allow for in-chamber imaging with minimal distortion. Specialized tissue processing and wax removal apparatuses are also disclosed including for use with tissue chambers having frangible portions to permit ease of wax removal.