Provided are a gene detection kit and a gene detection device. The gene detection kit includes a kit body, a piston cylinder, and a piston. The kit body has an accommodating cavity and a plurality of reagent cavities. The piston cylinder is provided in the accommodating cavity, and the piston cylinder has a piston cavity. The piston is movably provided in the piston cavity along an axial direction of the piston cylinder. A first channel in communication with the piston cavity is provided on an outer circumferential surface of the piston cylinder, a plurality of second channels are provided on an inner wall of the accommodating cavity, each of the second channels is in corresponding communication with one of the reagent cavities, and the piston cylinder can move relative to the kit body, so that the plurality of second channels are alternately in communication with the first channel.

Described herein are digital microfluidic (DMF) devices and corresponding methods for managing reagent solution evaporation during a reaction. Reactions on the DMF devices described here are performed in an air or gas matrix. The DMF devices include a means for performing reactions at different temperatures. To address the issue of evaporation of the reaction droplet especially when the reaction is performed at higher temperatures, a means for introducing a replenishing droplet has been incorporated into the DMF device. A replenishing droplet is introduced every time when it has been determined that the reaction droplet has fallen below a threshold volume. Detection and monitoring of the reaction droplet may be through visual, optical, fluorescence, colorimetric, and/or electrical means.

The present invention generally relates to droplet libraries and to systems and methods for the formation of libraries of droplets. The present invention also relates to methods utilizing these droplet libraries in various biological, chemical, or diagnostic assays.

There is provided a microfluidic device comprising a first region configured to hold target cells, e.g., tumor cells, a second region configured to hold effector cells, e.g., immune cells, and an array of microstructures disposed between the first and second regions, wherein the first region is in fluid communication with the second region, and wherein the array of microstructures is configured to selectively allow movement of immune cells, from the second region to an interaction zone that is at least partially disposed within the first region, for interaction with tumor cells in the interaction zone. The array of microstructures can be an array of micropillars. Also provided is a chip comprising a plurality of the device and a method of studying interactions of a first cell type with a second cell type.

An embodiment of the present disclosure provides a liquid collector that collects liquid, the liquid collector including: a flow passage member including a flow passage that connects one end and other end of the flow passage member; a contact member that is disposed at the one end of the flow passage member, that includes an elastic material, and that is configured to come into contact with a target from which liquid is to be collected; and a container that receives the liquid discharged from the flow passage at the other end of the flow passage member.

A flow channel structure for removing a foreign substance, including a first flow channel, where the first flow channel has a first region having a depth shallower than a depth of another region. A method for removing a foreign substance in a fluid, including flowing the fluid to the first flow channel of the flow channel structure for removing a foreign substance.

Examples herein provide a device. The device includes a sample delivery component, which includes: a reagent chamber to contain at least one reagent; a sample chamber to contain a fluid sample; and a delivery channel extending from the reagent chamber and in fluid communication with the sample chamber and an output port, wherein the delivery channel is conducive mixing the at least one reagent and the fluid sample to form a mixture before the mixture reaches the output port and be discharged therefrom. The device includes a testing cassette detachable from the delivery component, which includes: an input port in fluid communication with a microfluidic reservoir, the input port to receive the discharged fluid sample from the output port; and a micro-fabricated integrated sensor in a microfluidic channel extending from the microfluidic reservoir.

Analytical assay reaction cartridges are disclosed that include a reagent tray containing a liquid reagent disposed therein and a flexible cover removably attached thereto. The flexible cover has a portion that extends beyond the reagent tray and that forms a tab portion extends through an opening in a lid member of the cartridge in order to facilitate removal of at least a portion of the cover and release of the liquid reagent. Also disclosed are analytical assay reaction kits that include the cartridges and diagnostic instruments for use with the analytical assay reaction cartridges/kits, as well as methods of making and using the cartridges/kits.

The present invention provides devices and methods for generating a pulsatile fluid flow in a microchannel by means of external actuation of a thin flexible film. With the devices described herein, cycles of positive and negative actuation can be used to infuse or withdrawal fluid in a microchannel. Fluid can be recirculated over one or more microfluidic feature, such as a chemical or molecular receptor, biosensor, electrode, cell or biological material, chromatography feature, mixer, etc., in a way that would represent an advantage over the single-pass flow techniques common to most microfluidic devices. The devices and methods are particularly useful in vitro diagnostics (IVD), analytical chemistry, chromatography, and mixing applications in a variety of fields.

An immunoassay device for use in quantitatively measuring an amount of an analyte in a fluid sample, employs reagents that include particle pairs comprising a) one of an antigen and antibody coupled with a label, and b) a magnetic particle coupled with the other of the antigen and antibody. A transport which moves a set of reaction wells along a path and a dispenser dispenses respective ones of the reagents into the reaction wells. Prior to magnetic separation and optical analysis, a controller that coordinates movement of the transport with operation of the pipette modules operates the transport to reciprocate the set of reaction wells along the path for mixing the fluid sample with the reagents.