A coagulation test device for measuring clotting time and clot characteristics of a whole blood sample under different hemostatic conditions. Results of the test are used as an aid in management of patients with coagulopathy of unknown etiology in order to help the physician determine appropriate clinical action to arrest bleeding in a patient.

The present invention provides novel microfluidic substrates and methods that are useful for performing biological, chemical and diagnostic assays. The substrates can include a plurality of electrically addressable, channel bearing fluidic modules integrally arranged such that a continuous channel is provided for flow of immiscible fluids.

A cassette assembly (1) comprises a cover (100), two cassette halves (200A, 200B) and a slider (300) comprising multiple test chambers (302). The cassette halves (200A, 200B) comprise waste tanks (230) in fluid connection with reservoirs (240), prefilled in one of the cassette halves (200A, 200B) with test agents. The particular design of the cassette halves (200A, 200B) enable forming predefined 5 volumes of liquid to achieve predefined concentrations of the test agents in the reservoirs (240) in one of the cassette halves (200A, 200B) and liquid in the reservoirs (240) in the other of the cassette halves (200A, 200B). Gradients of the test agents can then be established over the multiple test chambers (302).

The present disclosure provides a microfluidic chip and a droplet separation method, and belongs to the field of biological chip technology. The microfluidic chip includes a first liquid tank and a second liquid tank opposite to each other and a channel layer therebetween. The channel layer includes a plurality of microfluidic channels separated from each other, first ends of the microfluidic channels are communicated with the first liquid tank, and second ends are communicated with the second liquid tank. The first liquid tank contains sample solution to be detected, and the second liquid tank contains encapsulating liquid. The sample solution to be detected entering the first liquid tank may be separated into a plurality of sample droplets through the microfluidic channels, the separated sample droplets enter the second liquid tank, so that the encapsulating liquid is encapsulated on a surface of each of the plurality of sample droplets.

The present invention relates to an apparatus for controlling the shape and/or position of a moveable fluid-fluid meniscus, and methods of use, in particular a method to control the shape of a moveable fluid-fluid meniscus in an apparatus in which the meniscus is caused to align along a stable capillary barrier or phaseguide.

A microfluidic device includes a plurality of reaction wells; and a plurality of solid supports, and each of the solid supports has a reagent attached thereto. The reagent is attached to the solid support via a labile reagent/support bond such that the reagent is configured to be cleaved from the support via a cleaving operation.

A method of performing a separation of a sample of a disperse fluid comprises the steps of: i. providing a sample of a disperse fluid comprising particles dispersed in a fluid, wherein the particles comprises at least a first type of particle and at least a second type of particles, wherein the absolute value of the acoustic contrast of the first type of particle, relative to the fluid, is lower than the absolute value of the acoustic contrast of the second type of particle relative to the fluid, and wherein the first and second type of particle either both have a positive acoustic contrast, or alternatively a negative acoustic contrast, relative to the fluid, ii. positioning the sample in a microfluidic cavity, iii. subjecting the sample, in the microfluidic cavity, to an acoustic standing wave configured for causing the first and second type of particle to congregate in at least one first region of the cavity, thereby causing the fluid to occupy at least one second region of the cavity, and thereby defining at least one interface between the first region and the second region, and iv. collecting at least a portion of the first region adjacent and along the at least one interface to obtain the first type of particles. A system is also disclosed.

Disclosed are high-throughput vessel sorting systems and methods of sorting sample vessels, such as samples stored in test tubes. A system for sorting a plurality of individual vessels that each contains a sample is disclosed.

A microfabricated sheath flow structure for producing a sheath flow includes a primary sheath flow channel for conveying a sheath fluid, a sample inlet for injecting a sample into the sheath fluid in the primary sheath flow channel, a primary focusing region for focusing the sample within the sheath fluid and a secondary focusing region for providing additional focusing of the sample within the sheath fluid. The secondary focusing region may be formed by a flow channel intersecting the primary sheath flow channel to inject additional sheath fluid into the primary sheath flow channel from a selected direction. A sheath flow system may comprise a plurality of sheath flow structures operating in parallel on a microfluidic chip.

An optical measurement instrument is an integrated instrument that includes an optical cavity with a light source, a sample cuvette, and an optical sensor. The light source and sensor are on a bench that is on a translational or rotational mechanical platform such that optical beam can be moved to multiple sample containers. Each sample containers holds a distinct microorganism-attracting substance and a portion of a fluid sample containing an unknown microorganism. Each distinct microorganism-attracting substance is configured to bind with a single type of microorganism. The unknown microorganism in the fluid sample binds with the distinct microorganism-attracting substance in a single sample container. The instrument incubates the microorganism in the single sample container and detects the presence of the microorganism in the single sample container to thereby simultaneously identify the unknown microorganism.