This disclosure relates to equipment utilized to manufacture chemical agents, particularly biopharmaceuticals, using Disposable Containers (DCs).

This present invention concerns a single use aseptic kit comprising: a disaggregation module for receipt and processing of material comprising solid mammalian tissue; and a stabilization module for storing disaggregated product material, wherein each of said modules comprises one or more flexible containers connected by one or more conduits adapted to enable flow of the tissue material there between; and wherein each of said modules comprises one or more ports to permit aseptic input of media and/or reagents into the one or more flexible containers. The invention further relates to an automated device for semi-automated aseptic disaggregation and/or enrichment and/or stabilisation of cells or cell aggregates from mammalian solid tissue comprising a programmable processor and the single use aseptic kit. The invention further relates to a semi-automatic aseptic tissue processing method.

A bioreactor system is provided that includes a cell culture vessel having a first end, a second end, and at least one reservoir between the first and second ends; and a cell culture matrix disposed in the at least one reservoir. The cell culture matrix has a structurally defined substrate with a surface for adhering cells thereto. The bioreactor system flows material through the at least one reservoir and through the cell culture matrix in a flow direction from the first end to the second end, and the cell culture matrix exhibits isotropic fluid flow permeability therethrough.

The present invention relates to smart tank for a bio-pharma process line, a smart tank assembly, a method for assembling a smart tank and a system comprising multiple smart tanks. The smart tank comprises a top plate element, at least one sidewall element, and a bottom plate element, wherein the top plate element, the at least one sidewall element and the bottom plate element are arranged to form a reservoir for receiving at least one biochemical medium. The smart tank comprises further at least one channel, for guiding the at least one biochemical medium and/or an operating medium.

A method for separating motile organisms from other organisms. The method comprises controlling a fluid delivery unit to provide a fluid flow to a sample separating device (302). The fluid flow has a sample introduction flow velocity set so that a sample may be introduced into a sample introduction zone of the device. The sample introduction flow velocity is sufficiently high such that an organism in the sample is unable to exit the sample introduction zone. The method comprises controlling the fluid delivery unit to reduce the fluid flow velocity from the sample introduction flow velocity to an operational flow velocity lower than the sample introduction flow velocity (303). The operational flow velocity is selected such that motile organisms in the sample are able to swim against the fluid flow and enter a sample collection zone of the device.

A device for homogenizing a multicomponent fluid including a main channel, a first and a second buffer channels, a collector connected to the main channel with a main conduct, to the first buffer channel with a first fiber and to the second buffer channel with a second fiber. The collector further includes a flow separation point aimed at dividing the main conduct into the first and second fibers, a pumping unit configured to move the multicomponent fluid from the main channel to the first or the second buffer channels through the collector and move the multicomponent fluid from the first or the second buffer channels to the main channel through the collector.

A microfluidic device for cell culture and screening, including a covering element with a plurality of openings configured for introducing and collecting fluids, and a central through hole; an intermediate element with a plurality of microchannels, a plurality of supply tanks and at least one waste tank, and a blind bottom cavity; a lower element, with a collecting tank and a recessed central portion; and a slide housed in a housing pocket. The intermediate element is interposed between the covering element and the lower element to form an upper optical window and at least one culture chamber. The plurality of microchannels puts in fluid communication the plurality of supply tanks, the at least one culture chamber and the waste tank.

This invention relates to a tissue construct comprising a core portion having a recess and composed of fibrous connective tissue, and loose fibrous somatic stem cell-accumulated tissue comprising type III collagen and somatic stem cells which is formed in the recess; a device for producing the same; and a method for collecting somatic stem cells from the tissue construct.

Presented is an airway organ bioreactor apparatus, and methods of use thereof, as well as bioartificial airway organs produced using the methods, and methods of treating subjects using the bioartificial airway organs. The bioreactor comprises: an organ chamber: an ingres line connecting the organ chamber and a reservoir system and comprising an arterial line, a venous line and a tracheal line; an egress line connecting the chamber and the reservoir system, pumps in ingress and egress lines; a controller to control fluid exchange; a chamber pressure sensor connected to the organ chamber.

A microporous substrate for detection of surface bound target analyte molecules includes a microporous substrate material having opposed surfaces and tapered micropores extending through the substrate with the micropores having wider openings on one side of the substrate compared to the other side. The micropores have bound therein analyte specific receptors complementary to the target molecules. When a liquid sample containing the target analyte molecules with optical probes attached to the target molecules is flowed through the substrate, they bind to their complementary analyte specific receptors and emit light. This microporous substrate structure gives an increase in the collection efficiency of light emitted from optical probes when the light is detected by a light detector spaced from the side of the microporous substrate facing the larger micropores openings compared to a light collection efficiency of light emitted from the optical probes when the micropores are straight and not tapered.