A mixing system includes a tank assembly and a container positioned within the tank assembly, the container bounding a compartment. A mixer is disposed within the compartment of the container. A shaft has a first end secured to the mixer and an opposing second end disposed outside of the container. An actuation mechanism is coupled with the second end of the shaft outside of the container and reciprocally moves the shaft and the mixer a stroke length, the stroke length being adjusted based on a pre-programmed protocol or signals from a sensor.

A shaking system of cell culture includes a shaking unit, a side visual unit, a top visual unit and a control unit. The side visual unit is located at one side of the shaking unit. The top visual unit is located above the shaking unit. The control unit is coupled signally with the shaking unit, the side visual and the top visual unit. In addition, a shaking method of cell culture is provided as well.

A mixing container 1 with a top filling opening 5, with a connection flange 9, 9.1 which projects outward in the area of the top filling opening 5 in a radial direction for connecting the mixing container 1 to the mixing head of an industrial mixing machine and with a bottom discharge 13 that can be blocked and opened comprises a mixing receptacle 3, 3.1 forming the hollow chamber 4 of the mixing container 1 and with a wall 18, 19 encompassing its hollow chamber and flexible in a radial direction and comprises a container frame 2 holding the mixing receptacle 3, 3,1 and with the connection flange 9 and the discharge 13. The container frame 2 holds the mixing receptacle 3, 3.1, in such a manner that its wall 18, 19 surrounding the hollow chamber 4 is at least partially accessible in the circumferential direction for bringing about a deformation of it in the radial direction.

A method of preparing reagents includes inserting a cartridge into an instrument. The cartridge includes a plurality of reagent enclosures disposed in a cavity of the cartridge and exposing a port to an exterior of the cartridge. Each reagent enclosure includes a reagent container including a reagent and an internal cavity defining a compressible volume, an opening defined through the reagent container to the internal cavity. The method further includes connecting a plurality of fluid ports to the openings of the plurality of reagent enclosures; applying a solution through the fluid ports to at least partially fill the plurality of reagent enclosures; and cycling a pressure of the cavity, whereby for each of the reagent enclosures, during increasing pressure, the solution enters the internal cavity of the reagent container, combines with the reagent, and compresses the compressible volume, and during decreasing pressure, the compressible volume decreases and the reagent is ejected through the opening.

Disclosed herein are devices and methods for the detection, quantification and/or monitoring of analytes. The systems and methods can be used, for example, to rapidly monitor gases downhole in a well.

A method of preparing reagents includes inserting a cartridge into an instrument. The cartridge includes a plurality of reagent enclosures disposed in a cavity of the cartridge and exposing a port to an exterior of the cartridge. Each reagent enclosure includes a reagent container including a reagent and an internal cavity defining a compressible volume, an opening defined through the reagent container to the internal cavity. The method further includes connecting a plurality of fluid ports to the openings of the plurality of reagent enclosures; applying a solution through the fluid ports to at least partially fill the plurality of reagent enclosures; and cycling a pressure of the cavity, whereby for each of the reagent enclosures, during increasing pressure, the solution enters the internal cavity of the reagent container, combines with the reagent, and compresses the compressible volume, and during decreasing pressure, the compressible volume decreases and the reagent is ejected through the opening.

A mixing apparatus is for selective mixing of contents. The mixing apparatus has a body that defines an interior space. The body further has an aperture for permitting access to the interior space. The body has at least a portion that is collapsible and configured to be gripped and repositioned by a user to collapse a part of the body into the interior space to alter at least one of: the volume of the interior space; and the shape of the interior space. The mixing apparatus further has at least one mixing member located within the interior space that is configured and located so that the contents is forced against the at least one mixing member when the collapsible portion is gripped and repositioned by a user.

A disposable, point-of-care diagnostic cartridge and method of performing an invitro diagnostic test on a specimen are provided. The cartridge includes a base having a mixing chamber is formed thereon. The mixing chamber has a mixing chamber inlet and a mixing chamber outlet. A detection chamber is formed downstream from the mixing chamber in fluid communication therewith. The mixing chamber includes a mixing reservoir bounded at least in part by a flexible upper member. The flexible upper member is expandable to accommodate an increase in volume of fluid and collapsible to dispense fluid outwardly from the mixing reservoir. The mixing chamber inlet has an inlet valve member that provides one way flow of fluid into the mixing reservoir. The mixing chamber outlet has an outlet valve member that provides one way flow of fluid outwardly from the mixing reservoir to the detection chamber.

A method of preparing reagents includes inserting a cartridge into an instrument. The cartridge includes a plurality of reagent enclosures disposed in a cavity of the cartridge and exposing a port to an exterior of the cartridge. Each reagent enclosure includes a reagent container including a reagent and an internal cavity defining a compressible volume, an opening defined through the reagent container to the internal cavity. The method further includes connecting a plurality of fluid ports to the openings of the plurality of reagent enclosures; applying a solution through the fluid ports to at least partially fill the plurality of reagent enclosures; and cycling a pressure of the cavity, whereby for each of the reagent enclosures, during increasing pressure, the solution enters the internal cavity of the reagent container, combines with the reagent, and compresses the compressible volume, and during decreasing pressure, the compressible volume decreases and the reagent is ejected through the opening.

A mixing system includes a tank assembly and a container positioned within the tank assembly, the container bounding a compartment. A mixer is disposed within the compartment of the container. A shaft has a first end secured to the mixer and an opposing second end disposed outside of the container. An actuation mechanism is coupled with the second end of the shaft outside of the container and reciprocally moves the shaft and the mixer a stroke length, the stroke length being adjusted based on a pre-programmed protocol or signals from a sensor.