A sample chamber holder for MAS-NMR capable of operating at both low and high pressures. In one example the sample chamber holder is made up of a sample holder body defining a sample chamber therein, a connector configured to operatively statically hold an in situ rotor within the sample chamber; a coupler configured to operatively connect the sampler holder body to a magnetically coupled rotation member. The magnetically coupled rotation member is configured to engage and rotate a sealing cap from an NMR rotor in such a way so as to allow an NMR cap to be alternatively opened or sealed in-situ while the NMR rotor remains statically positioned in an NMR device.

A flow cell includes a flow cell body. The flow cell body includes a frame and a fluid chamber defined in the flow cell body. The fluid chamber includes a reaction region allowing a fluid flow. A liquid inlet, a liquid outlet, and two exhaust holes connected to the fluid chamber are in the frame. Fluid into the liquid inlet flows through the reaction region in the fluid chamber and flows out through the liquid outlet. The exhaust holes discharge gas generated in the fluid chamber during the fluid flow. A flow cell with integral sealing rings and a biochemical substance reaction device are also disclosed.

Microfluidic pumps are provided that use electrowetting to manipulate the location of one or more droplets of a working fluid (e.g., water) in order to pump tears, blood, laboratory samples, carrier fluid, or some other payload fluid. The working fluid is separated from the payload fluid by one or more droplets of an isolating fluid that is immiscible with the working fluid. The working fluid is manipulated via electrowetting, by applying voltages to two or more electrodes, to repeatedly move back and forth. Forces, pressures, and/or fluid flows exerted by the working fluid are coupled to the payload fluid via the droplet(s) of isolation fluid and reed valves, diffuser nozzles, or other varieties of valve can act as flow-rectifying elements to convert the coupled forces into a net flow of the payload fluid through the pump.

Methods of detecting the presence of toxins in a sample using electrophoretic separations and of performing electrophoretic separation of complex samples are provided. The method of detecting the presence of toxins includes reacting a sample and a substrate with a signaling enzyme which converts the substrate to the product in a reaction medium, introducing a run buffer into a separation channel having an inlet end, selectively introducing at least one of the substrate and the product of the reaction medium into the inlet end of the separation channel, electrophoretically separating the substrate and the product, and determining the rate of conversion of the substrate to the product, wherein a change in the rate of conversion is indicative of the presence of toxins. The method of performing electrophoretic separations of complex samples having charged particulates and oppositely charged analytes comprising introducing a run buffer into a separation channel having an inlet end, selectively introducing the oppositely charged analytes in the complex sample into the separation channel, and electrophoretically separating the charged particulates and the oppositely charged analytes. Additionally, a device for varying with respect to time the bulk flow of a fluid in a separation channel of an electrophoretic device having a buffer reservoir in fluid contact with the separation channel is provided. The device includes a pressure sensor in fluid contact with a buffer reservoir, a high pressure reservoir in selective fluidic communication with the buffer reservoir, a low pressure reservoir in selective fluidic communication with the buffer reservoir and in fluidic communication with the high pressure reservoir, and a pumping device for pumping a gas from the low pressure reservoir to the high pressure reservoir.

A sample collection device having a sample container, a solid phase binding material, and a container sealing component is presented. The sample container may have a housing that forms an opening for receiving a sample, and that encloses a space for holding the sample. The solid phase binding material may be disposed within the space enclosed by the housing of the sample container and may be adapted, when the sample contains an analyte, to bind specifically to the analyte. The container sealing component may be removably attachable to the sample container at the opening thereof, and may be adapted, when attached to the sample container, to form a seal around the opening of the sample container.

The invention relates to a device for analyzing solid biological elements and to a device for implementing same. The device comprises a plate (1) of tubes, the lower ends (2) of which are perforated and the upper ends (4) of which are open on the tube plate (1) to allow the introduction of an element to be analyzed (5), a deep-well plate (6) into which the tube plate (1) is inserted and a lifter (7) for raising the tube plate (1) from the deep-well plate (6). Each tube (3) in the tube plate (1) comprises at least one opening (9) toward its upper end (4) to allow air to pass through and each tube (3) can be closed at its upper end (4) with a stopper (8). The invention is applicable particularly in the medical, agri-food and forensic science fields.

A cartridge includes: a first reservoir capable of accommodating a sample liquid; a sheath liquid conduit; a sterilization filter; a mixer; a nozzle; a droplet collection member; and a check valve. The sterilization filter is provided at the sheath liquid conduit. The check valve is connected to a waste-droplet collection member. A sample liquid flow path and a sheath liquid flow path are isolated from a surrounding environment around the cartridge and are maintained in a sterile state. The sample liquid flow path extends from the first reservoir to the droplet collection member. The sheath liquid flow path extends from the sterilization filter to the droplet collection member.

The presently disclosed subject matter provides devices and methods for sample extraction from a swab during biological sample processing. In particular embodiments, the devices and methods are configured for use in conjunction with microfluidic devices for sample processing.

A transfer container for a fluid includes a tube, the tube including a conical portion at one end, the tube defining an interior space and one or more fluid passages configured to allow flow of fluid into or out of the interior space of the tube. The transfer container also includes a connector configured to seal the end of the conical portion when the connector is joined only to the conical portion and a pressure control mechanism configured to increase or decrease a pressure in the interior space of the tube. The transfer container can be used in a method including connecting fluid lines to the fluid passages, adding a fluid including cryoprotectant and cells, centrifuging the transfer container, and then connecting the transfer container to a second fluid transfer container containing another fluid. This allows the sterile transfer of fluids and separation of cells from cryoprotectant.

A tubing-free, sample-to-droplet microfluidic system includes a tubing-free, sample-to-droplet microfluidic chip; a valve control system connected to the tubing-free, sample-to-droplet microfluidic chip; a vacuum system fluidly connected to the tubing-free, sample-to-droplet microfluidic chip; and a droplet formation pressure system fluidly connected to the tubing-free, sample-to-droplet microfluidic chip. A microfluidic chip for a tubing-free, sample-to-droplet microfluidic system includes a tubing-free, sample-to-droplet interface section; a droplet mixing section in fluid connection with the tubing-free, sample-to-droplet interface section to received droplets therefrom; an incubation section in fluid connection with the droplet mixing section to receive droplets therefrom; and a detection section in fluid connection with the incubation section to receive droplets therefrom.