A positioning apparatus for restraining an object includes a base plate, an attachment plate, and a securing element. The base plate may include guides into which protrusions of the attachment plate slide to alter the positioning apparatus from an open position to a closed position. The base plate also includes receivers to receive tubular members, which have their movement restrained by the receivers and the securing elements in the closed position. The positioning apparatus may also include a latch to help maintain the closed position during operation.

A fluid handling device includes a board that includes a board body, and a lid that faces the first surface of the board and is disposed so as to form a space between the board and the lid. The lid includes a lid body including a second surface, and a first through hole which allows for injection of a fluid into the space and includes a first opening that opens onto the second surface and a second opening that opens onto a surface other than the second surface. The lid further includes a spacer which is integrally molded with the lid body; alternatively, the board includes a spacer which is integrally molded with the board body.

Disclosed is a fluid disposing system including a centrifugal separator that centrifugally separates a liquid that is supplied, a reagent supply module provided on one side of the centrifugal separator and that supplies a reagent to the centrifugal separator, a pipetting module provided at an upper portion of the centrifugal separator and that feeds a fluid to the centrifugal separator, a feeding module coupled to one side of the pipetting module, and that moves the pipetting module in an X axis direction and a Y axis direction corresponding to a horizontal direction, and a Z axis direction that is perpendicular to the horizontal direction, and a separation module including a magnetic bead for magnetically separating a material that has been primarily separated by the centrifugal separator.

Materials and methods of making have been developed for mass production of thermoplastic microfluidic chips. An elastomer diaphragm with a stress relieving feature can be used in microfluidic valves, pump diaphragms, and diaphragm micropumps. An optimized pump chamber design for complete fluid displacement and chamber geometry are provided. Microfluidic pressure regulators use a pneumatically actuated elastic membrane in a back-pressure regulator configuration. Microfluidic accumulators store pressurized fluid in a microfluidic chip. Removable caps for cell culture and a quick release top are described. Methods to incorporate hydrogels and ECM scaffolds have been developed. Electro pneumatic manifolds connect and control of multiple microfluidic devices vertically or on a rotary mechanism.

A microtiter plate mixing control system is disclosed. The system includes a frame, a suspension system attached to the frame, and a magnetically responsive horizontal platform supported on the frame by the suspension system. A solenoid is adjacent the platform for moving the platform on the suspension system. A proximity sensor is adjacent the platform for determining the position of the platform with respect to the frame. A controller is in communication with the proximity sensor and the solenoid for driving the solenoid and moving the platform in response to the proximity sensor.

A microfluidic device for image multiplexing includes a base structure and a fluid well insert. The base structure comprises an optical window. The fluid well insert configured to be coupled to the base structure and to retain a microscope slide for mounting a biological sample within the microfluidic device. The fluid well insert is further configured to provide a fluid to the biological sample. A fluid well insert lid is coupled to the fluid well insert or the fluid well insert comprises a fluid well insert lid.

The present invention relates to a microfluidic device 100 for image multiplexing. The microfluidic device 100 comprises a base structure 110 comprising an optical window 140 and a fluid well insert 120 coupled to the base structure 110. The fluid well insert 120 is configured to retain a microscope slide 130 for mounting of a biological sample 150 within the microfluidic device 100. The fluid well insert 120 is also configured to provide a fluid to said biological sample 150. A fluid well insert lid 160 coupled to the fluid well insert 120 is also provided.

This disclosure is directed to an apparatus, system and method for retrieving a target material from a suspension. A system includes a plurality of processing vessels and a collector. The collector funnels portions of the target material from the suspension through a cannula and into the processing vessels. Sequential density fractionation is the division of a sample into fractions or of a fraction of a sample into sub-fractions by a step-wise or sequential process, such that each step or sequence results in the collection or separation of a different fraction or sub-fraction from the preceding and successive steps or sequences. In other words, sequential density fractionation provides individual sub-populations of a population or individual sub-sub-populations of a sub-population of a population through a series of steps.

A configurable device arrangement for performing at least one unit operation in a biopharmaceutical process includes a base rack and a plurality of holders for releasable direct or indirect attachment of process components, in particular single-use process components, for the unit operation. The holders are in turn adapted to be releasably attached directly or indirectly to the base rack. The device arrangement further includes a positioning system which defines specific positions for the holders relative to the base rack.

In an acid digestion reaction performed in a vessel, an elastic lid or septum can be mounted to the mouth of the vessel with a flanged band. In response to determining that a predetermined pressure has been reached in the vessel, a closing force being applied to the lid or septum can be reduced to initiate venting from the vessel. One or more parameters, including the closing force, can be monitored during the venting, and the closing force can be responsively adjusted to optimize the venting. The closing force can be provided by a clamping apparatus that may or may not include a hydraulic system. The clamping apparatus can be configured to increase the closing force in response to increased hydraulic pressure in the hydraulic system. The clamping apparatus can include an engager having an upwardly extending recess extending at least partially around a downwardly protruding portion of the engager.