System for performing a flow-based assay. The system may comprise a droplet generator to produce an emulsion including droplets in a carrier fluid. The system also may comprise a thermocycler including two or more temperature-controlled zones and also including a channel connected to the droplet generator for receiving the emulsion. The channel may form a single-pass continuous fluid route traversing the temperature-controlled zones multiple times, such that droplets passing through the channel are thermally cycled. The system further may comprise a detection station downstream from the thermocycler and configured to detect a signal from the droplets after such droplets have been thermally cycled by passing through the channel.

A stirring bar capable of reducing a dead space inside a container and efficiently using a contained liquid. A stirring bar introduced into a reagent bottle having an opening mouth portion and rotated by a magnetic force transmitted from the outside of the reagent bottle so as to stir a reagent in the reagent bottle, including: a magnet having a predetermined shape; and a main body including a magnetic member therein, in which the main body is provided with a through-hole which has an opening area corresponding to an opened area and is able to receive a nozzle in the opening area, and in which the stirring bar in a rotation state is able to receive the nozzle in a circular center area narrower than the opening area and having a diameter of an opening width of a center portion of the opening area.

A microfluidic mixer, formed by two parts, a first part being a substrate having formations defining fluid channels on an outer surface that is directed towards a second part, which is a flexible layer. The flexile layer has formations defining a fluid channel which, when the flexible layer is positioned over the substrate so as to cover the fluid channels of the substrate provides a fluid communication path. A section of said communication path comprises at least first and second fluid channels for providing first and second fluids. The first and second fluid channels merge before an inlet of a mixing chamber. The mixing chamber comprises perturbation formations. An outlet of the mixing chamber is connected to an outlet fluid channel. The flexible layer comprises points for compression at the inlet and outlet of the mixing chamber for closing the merged fluid channel. The perturbation formations of the mixing chamber are vertically arranged vertically with respect to an inner surface.

Certain embodiments are directed to finite step emulsification device and/or methods that combine finite step emulsification with gradients of confinement for the formation of a 2D monolayer array of droplets with low size dispersion.

The present invention relates to a shaking platform for a laboratory shaking device having an adjustable holding device for fastening at least one container, the shaking platform having a length and a width, and the holding device comprising: a base plate having a fastening device for fastening the holding device on the shaking platform, at least two supports that protrude from the base plate and that form a container-receiving space arranged between the supports, and at least two holding rods carried by the supports and running substantially parallel to the shaking platform, which holding rods delimit the container-receiving space and whose distance from one another can be adjusted via an adjusting rail, the length and the width being greater than a length of the holding rods. The present invention also relates to an adjustable holding device and a laboratory shaking device.

Provided herein are apparatuses and systems for mixing liquids and suspensions that include vessels with structures that improve mixing while not contacting liquid delivery components. The apparatuses and systems can include a motor drive that allows speed and directional control of rotation of the vessel. The apparatuses and systems can include one or more magnets for separating magnetic beads in a suspension. Also provided are methods using said apparatuses and systems for mixing and separation processes.

What is disclosed in the present invention is to provide a quantitative transfer pipette structure, wherein an anti-backflow compartment is configured in the first bulb. The dimensions and locations of the first bulb, the second bulb and the third bulb are specifically configured to aspirate and transfer a specific volume of the liquid to a container, mix the liquid with the substance in the container by pressing and releasing the specific bulbs, so as to achieve the effects of precise quantification and sufficient mixing.

The invention relates to an arrangement for preparing a plurality of samples for an analytical method, comprising a carousel with a solid housing and moveable receiving parts for the sample containers; a control for controlling the receiving parts in the carousel; and a sample receiving device for providing the sample for the analytical method. Said arrangement is characterized in that one or more stations for preparing samples are provided on the carousel, the receiving parts for the sample containers of the carousel can be positioned on said stations. Said arrangement also comprises a centrifuge with pairs of opposite lying receiving parts provided for the sample containers, and said receiving parts are arranged such that they can move on the centrifuge for the sample holder such that a transfer of a sample holder between a receiving part in the carousel and a receiving part in the centrifuge can be carried out. The control takes place by the same control which is also provided for controlling the carousel.

There is disclosed a capillary microfluidic circuit including a main channel communicating with a flow inducing element. The main channel has intermediary inlets. Reservoirs for containing one or more liquids prior to being drawn into the main channel. The reservoirs include a first reservoir and at least a second reservoir. Each of the reservoirs has an upstream end connectable to vents for filling the reservoirs with the one or more liquids and a downstream end. The downstream end of each of the reservoirs is connected to the intermediary inlets of the main channel A conduit is disposed between the first reservoir and the a least a second reservoir. The conduit links the downstream end of the first reservoir with the upstream end of the at least a second reservoir.

A diagnostic system for determining the presence of a target in a sample liquid that includes a diagnostic reader and a microfluidic strip having a microfluidic channel network therein. An actuator within the reader modifies the pressure of a gas in gaseous communication with a liquid-gas interface of a sample liquid within the microfluidic channel network to move and/or mix the sample liquid. The pressure modifications may be continuous and/or oscillatory.