A method for fluid transport includes receiving fluid at an inlet port of an inlet. The fluid is outputted through an opening of the inlet into a channel. A first ratio of a first distance to a second distance is substantially equal to a cubic root of a second ratio between a first length dimension and a second length dimension of the inlet, the first distance being measured from an entrance of the inlet port to a first position within the inlet, the second distance being measured from the entrance of the inlet port to a second position within the inlet, the first length dimension and the second length dimension each being measured along a direction orthogonal to a measurement direction along the first distance and the second distance, the first length dimension and the second length dimension being measured at the first position and the second position, respectively.

The present invention relates to a tube for collecting specimens. The tube includes a tubular body having an inner surface which defines a hollow space for carrying a carrier solution or the like. The tube also includes a plurality of ridges projecting inwardly from the inner surface for engagement with at least a portion of a specimen collection tool for facilitating release of at least some of specimens therefrom.

The present invention relates to a spiral microfluidic device and module for CTC separation from blood, a manufacturing method. When a blood sample and a body fluid sample are respectively injected into the inlet of the device by the method described below, viable CTCs can be isolated and used for the development of specific cancer cell lines. The device has two inlets with a radius of 10 mm or less, a two-loop helical microchannel having a uniform height of a radial inner portion and a radial outer portion, and a rectangular cross-section in which the width of the upper portion is equal to the width of the base, and the two-loop helical microchannel is branched from the CTC and two outlets through which blood cells are separately discharged. The present invention can provide a spiral microfluidic device and module for CTC isolation, a manufacturing method, which can lead to the development of a reported specific cell line by making it possible to isolate viable CTCs by a spiral microfluidic device for CTC isolation derive an effect.

A method of sample preparation for streamlined multi-step assays is provided. The method includes the step of providing a microfluidic device including a reservoir defined by a surface configured to repel an aqueous solution. A dried reagent is provided on a portion of the surface and the reservoir is filled with an oil. A first droplet formed from the aqueous solution is positioned on the dried reagent so to pick-up and re-dissolve the dried reagent therein so as to expose the portion of the surface. In addition, a second droplet of an aqueous solution may be deposited on a hydrophilic spot patterned on the surface. A magnetic force may be configured to interact magnetically with the paramagnetic beads within the first droplet to move the droplet through the oil in the reservoir or to move the paramagnetic beads from the first droplet, through the oil, into the second droplet.

A microfluidic system for fluid transport is provided. The microfluidic system includes a microfluidic device. The microfluidic device includes an inlet body including an inlet. The microfluidic device includes a base supporting the inlet body. The base includes a channel in fluid communication with the inlet. The base includes one or more sensors formed on a surface of the channel, or one or more sensors formed in one or more wells formed in the surface of the channel. The channel is configured to facilitate flow of the fluid. The fluid includes a plurality of beads. The fluid includes a plurality of suspended cells. The inlet is configured to receive the fluid at an inlet port. The inlet is configured to output the fluid through an opening in fluid communication with the channel. The inlet is configured to provide substantially uniform flow of the fluid across a substantial portion of a horizontal dimension of the channel. The device is configured to compensate for edge effects otherwise present therein. Related methods, apparatuses, systems, techniques and articles are also described.

A microfluidic chip includes a functional area, which is covered by a flexible or deformable cover. The cover has an expansion limiter. This expansion limiter can for example be embodied as a stable plate including one or more than one opening. The expansion limiter may be fixedly connected to the cover.

A microfluidic device includes a channel through which a reaction solution flows. The channel passes through a reaction section having a plurality of temperature zones set at predetermined different temperatures. The channel includes, at least in the reaction section, a region where a cross-sectional area decreases in a feeding direction of the reaction solution.

Embodiments for sorting particles are provided that include a microfluidic channel configured to receive a microfluidic flow that comprises a plurality of particles having different characteristics, the microfluidic channel having a plurality of output flow channels, a first detector configured to detect the location of the particles, a plurality of actuators located along the direction of the microfluidic flow and defining a sorting electrode arrangement. The microfluidic device further comprises a controller configured to receive signals from the first detector and to provide force field profiles for each of the plurality of particles, wherein each force field profile comprises a plurality of deflection force settings along the direction of the microfluidic flow. The controller individually addresses the plurality of actuators to generate a plurality of actuation inducing fields along the direction of the microfluidic flow to generate the deflection force settings in the force field profiles.

Methods described herein provide a way to reduce or eliminate drag and adhesion of a substance flowing over a surface by creating a vapor cushion via evaporation of a phase-changing material of or on the surface or encapsulated within textures of the surface. The vapor cushion causes the flowing substance to be suspended over the surface, greatly reducing friction, drag, and adhesion between the flowing substance and the surface. The temperature of the flowing substance is above the sublimation point and/or melting point of the phase-changing material. The phase-changing material undergoes a phase change (evaporation or sublimation) upon contact with the flowing substance due to local heat transfer from the flowing substance to the material, generating a vapor cushion between the solid or liquid material and the flowing substance.

Disclosed are devices and methods useful for confined-channel digital microfluidics that combine high-throughput droplet generators with digital microfluidic for droplet manipulation. The present disclosure also provides an off-chip sensing system for droplet tracking.