A microstructured surface is disclosed capable of immobilizing or resisting displacement forces with respect to a target surface. The microstructured surface is capable of generating capillary bridges with a target surface. The capillary bridges can be further stabilized to generate a novel liquid enhanced adhesion mechanism.

The present disclosure provides a cell harvesting method for the efficient sedimentation and retention of cells from liquid samples onto a solid support with low cell losses and low impact on cell morphology.

A microchannel device that can suppress a flow of a test solution produced between microchannels is provided. The microchannel device includes an opening for receiving a test solution that is to be injected therethrough, a main channel, a plurality of microchannels, a reservoir, an opening, and a gas permeable membrane. The plurality of microchannels include a first group and a second group. The microchannels included in each of the first group and the second group are arranged as being aligned in a direction of an X axis when the microchannel device is viewed in a plan view, and the first group and the second group are arranged as being aligned in a direction of a Y axis orthogonal to the direction of the X axis.

Embodiments of the present disclosure are directed to methods, systems and devices, for precise and reduced spot-size capabilities using a laser to alter surfaces without chemical treatment, chemical waste, or chemical residues is provided for microfluidic systems (e.g., lab-on-a-disk, for example). In some embodiments, hydrophobic and super-hydrophilic areas can be created on surfaces in the same material at different areas and positions merely by using different laser settings (e.g., spot size, wavelength, spacing, and/or pulse duration). Accordingly, capillary forces that are a recurrent issue in a microfluidic devices (e.g., a centrifugal microfluidic disk) can be controlled for practical applications, including, for example when users handle the disks and insert a sample, the moment the substrate/device (e.g., disk) is placed in a system (e.g., a centrifugal system), capillary forces can take place and move the fluids, which becomes a problem for sequential bioassays taking place in substrate/device (e.g., disk). Thus, in some embodiments, the systems, devices and methods increase fluid control in microfluidic devices.

The disclosure relates to methods of manufacturing and using a single layer microfluidic for detecting target analytes, including obtaining a single layer sheet of paper; depositing wax boundaries onto the paper in a plurality of patterns including a main channel, fluid transfer channels, and an independent diagnostic area corresponding to each fluid transfer channel; melting the wax through the paper; depositing diagnostic components onto the diagnostic areas; depositing a continuous wax backing; and cutting devices from the paper. The disclosure also relates to a method of capturing an image of the micro fluidic device to generate diagnostic results corresponding to the diagnostic components by: identifying at least two panels from the image; and determining a color for each panel of the at least two panels; and generating for display, using the computing device, a graphical user-interface including at least one component visualizing the diagnostic results.

An embodiment for a microfluidic device is provided. The device comprises two areas, arranged side-by-side, and a trigger channel. They include a first area, which is delimited by a first liquid pinning barrier, and a second area, which is delimited by a second liquid pinning barrier. The latter extends parallel to the first liquid pinning barrier to delimit a corridor. The trigger channel extends through the corridor between the two areas. In addition, the trigger channel connects the first liquid pinning barrier with the second liquid pinning barrier, allowing a first liquid pinned at the first liquid pinning barrier and a second liquid pinned at the second liquid pinning barrier to be contacted, each, by a reverse flow of the second liquid in the trigger channel and thereby start mixing at a level of the corridor, in operation. The invention is further directed to related methods of operation.

A device for dispensing one or more microdroplets is provided. The device comprising a microfluidic chip having an oEWOD structure configured to create an optically-mediated electrowetting (oEWOD) force, the microfluidic chip includes a first region and a second region, wherein said first and second regions are separated by a constriction; wherein the first region is adapted to receive and manipulate one or more microdroplets dispersed in a carrier fluid at first flow rate; and wherein the second region is configured to receive the microdroplet via the constriction from the first region and transfer said microdroplet to an outlet port of the microfluidic chip in a second flow rate; wherein the second region is configured to receive said microdroplet via the constriction from the first region by application of an optically -mediated electrowetting (oEWOD) force; and wherein the second flow rate in the second region is higher than the first flow rate in the first flow region. A method and apparatus for dispensing one or more microdroplets are also provided.

There is provided a master for micro flow path creation, a transfer copy, and a method for producing a master for micro flow path creation by which transfer copies having an area with high hydrophilicity can be easily mass-produced, the master for micro flow path creation including: a base material; a main concave-convex portion provided on a surface of the base material and extending in a planar direction of the base material; and a fine concave-convex portion provided on a surface of the main concave-convex portion and having a narrower pitch than the main concave-convex portion. The fine concave-convex portion has an arithmetic average roughness of 10 nm to 150 nm and has a specific surface area ratio of 1.1 to 3.0.

A sample holder (10) comprises a sample chamber (33), a gas reservoir (32) and an upper layer (20) covering over the sample chamber (33) and gas reservoir (32), wherein a bottom surface of the upper layer (20) comprises a microstructure array (23) which overlies at least a portion of a top periphery of the sample chamber (33), and wherein the microstructure array (23) is in communication with a gas path which extends to the gas reservoir (32), to allow gas exchange between the sample chamber (33) and the gas reservoir (32).

Provided are valveless microfluidic flowchips comprising fluid flow barrier structures or configurations. Further provided are systems and methods having increased fluid transfer control in a valveless microfluidic flowchip. The systems and methods can be used in the present valveless microfluidic flowchips as well as in currently available valveless microfluidic flowchips.