Multiplanar microfluidic devices are provided that facilitate direct transverse fluid communication between a first microfluidic channel a plurality of adjacent microfluidic channels, where the adjacent microfluidic channels reside both laterally adjacent and vertically adjacent to the first microfluidic channel, thereby facilitating transverse diffusion to or from the adjacent microfluidic channels in both lateral and vertical directions. Geometrical meniscus-pinning features, such as meniscus-pinning ridge structures, are provided between adjacent microfluidic channels to restrict transverse flow between the microfluidic channels. Accordingly, a gel structure may be formed within the first microfluidic channel and one or more of the adjacent microfluidic channels can function as a perfusion channel, for example, for delivering media to cells residing withing the gel structure. Such devices may be extended and/or arrayed to include multiple channels with laterally and vertically adjacent perfusion microfluidic channels, optionally with shared lateral perfusion microfluidic channels among adjacent pairs of devices.

The present invention is directed to sample test cards having an increased sample well capacity for analyzing biological or other test samples. In one embodiment, the sample test cards of the present invention comprises a fluid channel network disposed in both the first surface and the second surface and connecting the fluid intake port to the sample wells, the fluid channel network comprising at least one distribution channels, a plurality of fill channels operatively connected to the at least one distribution channel, a plurality of through-channels operatively connected to one or more of the fill channels and a plurality of horizontally orientated fill ports operatively connecting the fill channels to the sample wells.

A microchip includes a plurality of laminated elastic sheets. Each of the elastic sheets forming a first intermediate layer as an intermediate layer formed with the plurality of elastic sheets have an inadhesive section(s) for forming a first flow path on the first intermediate layer. Each of the elastic sheets for forming a second intermediate layer as an intermediate layer formed with the plurality of elastic sheets have an inadhesive section(s) for forming a second flow path on the second intermediate layer. An elastic sheet(s) interposed between the first and second intermediate layers has a connecting section(s) connecting the first flow path and the second flow path. A flow path width at the connecting section(s) of the first flow path is narrower than a flow path width at the connecting section(s) of the second flow path.

Embodiments herein disclose a method for fabricating high aspect ratio structures. The method includes depositing a predefined quantity of a viscoelastic fluid on a top surface of a bottom cell plate and compressing the viscoelastic fluid deposited on the top surface of the bottom cell plate using a bottom surface of a top cell plate. The viscoelastic fluid is a blend of a solvent and a polymer. At least one of the top cell plate and bottom cell plate comprises a plurality of lands, sealed source holes and/or unsealed source hole for penetration of a low-viscous fluid. Further, the method includes separating the top cell plate and the bottom cell plate to induce out of plane stretching of the high viscous fluid and obtaining a plurality of high aspect ratio structures between the top cell plate and the bottom cell plate due to the penetration of the low-viscous fluid.

Disclosed herein is a system to detect and characterize individual particles and cells using at least either optic or electric detection as the particle or cell flows through a microfluidic channel. The system also provides for sorting particles and cells or isolating individual particles and cells.

A rotary valve that includes a stator, a rotor and a plurality of sample channels. The stator includes a stator surface having an inlet port, an outlet port and a plurality of selectable ports. The rotor includes a rotor surface having a first rotor channel and a second rotor channel. The rotor is configurable in a plurality of rotor positions, each of which couples the inlet port to one of the selectable ports through the first rotor channel and couples the outlet port to another one of the selectable ports through the second rotor channel. The two selectable ports are coupled to each other through one of the sample channels. The rotor has a bypass state defined by a rotor position, or angular range of rotor positions, at which the inlet port is coupled to the outlet port through the second rotor channel.

Disclosed herein is an improved method for magnetic capture of target molecules (e.g., microbes) in a fluid. Kits and solid substrates for carrying the method described herein are also provided. In some embodiments, the methods, kits, and solid substrates described herein are optimized for separation and/or detection of microbes and microbe-associated molecular pattern (MAMP) (including, e.g., but not limited to, a cell component of microbes, lipopolysaccharides (LPS), and/or endotoxin).

The present invention relates to fluidic devices for preparing, processing, storing, preserving, and/or analyzing samples. In particular, the devices and related systems and methods allow for preparing and/or analyzing samples (e.g., biospecimen samples) by using one or more of capture regions and/or automated analysis.

A chip includes a micro-channel unit for hydraulically classifying cells in a blood sample. In a micro-channel unit, liquid flowing from a sub channel into a main channel pushes cells flowing in the main channel toward a side thereof on which a removal channel and a collection channel are disposed. Fluid containing non-nucleated RBCs among the pushed cells enters the removal channel, so that the non-nucleated RBCs are removed from a blood sample. A plurality of micro-channel units having the same patterns as each other are repeatedly stacked in a height direction. Inlets of the main channels, inlets of the sub channels, outlets of the removal channels, outlets of the collection channels, and outlets of the main channels, which are provided in the micro-channel units, are connected to respective pillar channels penetrating each of layers in a traversing manner.

Techniques regarding microfluidic chips with one or more vias filled with sacrificial plugs and/or manufacturing methods thereof are provided herein. For example, one or more embodiments described herein can comprise an apparatus, which can comprise a silicon device layer of a microfluidic chip comprising a plurality of vias extending through the silicon device layer. The plurality of vias comprise greater than or equal to about 100 vias per square centimeter of a surface of the silicon device layer and less than or equal to about 100,000 vias per square centimeter of the surface of the silicon device layer. Additionally, the apparatus can comprise a plurality of sacrificial plugs positioned in the plurality of vias.