Methods and devices are provided herein for identifying a cell population comprising an effector cell that exerts an extracellular effect. In one embodiment the method comprises retaining in a microreactor a cell population comprising one or more effector cells, wherein the contents of the microreactor further comprise a readout particle population comprising one or more readout particles, incubating the cell population and the readout particle population within the microreactor, assaying the cell population for the presence of the extracellular effect, wherein the readout particle population or subpopulation thereof provides a direct or indirect readout of the extracellular effect, and determining, based on the results of the assaying step, whether one or more effector cells within the cell population exerts the extracellular effect on the readout particle. If an extracellular effect is measured, the cell population is recovered for further analysis to determine the cell or cells responsible for the effect.

A technique for detection of probes in a microfluidic flow-through chamber involves a plurality of interface pinning reaction vessel formed by micro- or nano-structured relief patterning of a substrate. The relief patterning increases a surface area locally, and defines a plurality of separated interface pinning reaction vessels. The marked detection protocol may be supplied on a single layer of a stacked microfluidic chip, or the chamber may constitute a whole layer. The chip may be designed to be driven mechanically, pneumatically, hydraulically, centrifugally or by capillary action. Each vessel allows for a high density of probes, an effective region for developer-type or fluorescence-based marking, and efficient readout. Suitable probe liquids can be self-limiting to fill one vessel. Suitable developer liquids avoid dye bleeding across vessels during washing.

There is provided a method of making a fluidic system that comprises assembling a fluidic system comprising a first plate, a second plate and a membrane disposed between the first plate and the second plate; applying laser energy to the fluidic system to cause the first plate, the second plate and the membrane to melt at bonding areas; and allowing the bonding areas to cool down such that the first plate, the second plate and the membrane are bonded together.

The present disclosure pertains to a microfluidic platform. The microfluidic platform includes a top layer having a top inlet and outlet, a center layer having a center inlet and outlet, and a bottom layer having a bottom inlet and outlet. The microfluidic platform further includes a first porous membrane between the top and center layer, a second porous membrane between the center and bottom layer, a first electrode disposed on at least one of the top and bottom layers, and a second electrode disposed on at least one of the top and bottom layers. Additionally, the present disclosure pertains to a method for selective isolation. The method includes flowing a sample through a microfluidic platform, isolating a first component from the sample in a top layer, isolating a second component from the sample in a center layer, and isolating a third component from the sample in a bottom layer.

Devices, systems, and methods for trapping and manipulating portions of tissue are described. In an embodiment, the devices include an array of traps, wherein traps of the array of traps are shaped to trap a tissue sample; and a well is in registry and fluidic communication with a trap of the array of traps.

A bio-information detection substrate and a gene chip are provided. The substrate includes a first main surface, the first main surface includes a test region and a dummy region located around the test region, at least one accommodation region is disposed on the first main surface, and the accommodation region is located in the dummy region.

A multi-layered band and a method for manufacturing a multi-layered band are disclosed. The multi-layered band comprises a support (1) to hold at least one battery structure (10) formed by overlapped layers including a porous material (11) and two electroactive electrodes (12, 13), one oxidizing (12) and one reducing (13), separated at a certain distance between them and in touch with said porous material (11). The battery structure (10) is configured to be activated upon the addition of a fluid into a given region of the porous material (11) and to provide electrical energy while said fluid impregnates by capillarity the porous material (11). The overlapped layers are constituted by parallel strips extending longitudinally along the length of the support (1), such that said multi-layered band can be cut transversally providing individual batteries of a same or different width each including the porous material (11) and the electroactive electrodes (12, 13).

A digital microfluidic chip, a method for driving the same, and a digital microfluidic device are provided. The digital microfluidic chip includes a state transition layer configured to bear a droplet, and a light driving layer configured to provide light for controlling a lyophobicity-lyophobicity transition of the state transition layer to drive the droplet to move. The light driving layer includes light emitting units arranged in an array and provides light. The state transition layer realizes a lyophobicity-lyophobicity transition. The light driving layer controls the lyophobicity-lyophobicity transition by providing light to drive the droplet to move. An existing digital microfluidic chip has a complex structure and a high fabricating cost, while the digital microfluidic chip of the present disclosure has a simple structure, a simple fabricating process and a low fabricating cost, and can realize miniaturization and integration to a maximum extent.

A multi-layered microfluidic system featuring tissue chambers for cells in a first layer and a plurality of medium channels for culture medium in a second layer. The tissue chambers fluidly connect to the medium channels such that media flows from the medium channels to the tissue chambers, forming large-scale perfused capillary networks. The capillary networks can undergo angiogenesis and vertical anastomosis. The multi-layered configuration of the system of the present invention allows for flexibility in design.

An apparatus includes a fluid reservoir and a laminate fluidic circuit positioned above the fluid reservoir. The laminate fluidic circuit includes two or more layers laminated together to define a substantially planar substrate and one or more channels defined within the substrate. The laminate fluidic circuit includes a flexible conduit defined by a portion of the substrate encompassing an extent of at least one of the channels that is partially separated or separable from the remainder of the substrate. The flexible conduit is deflectable with respect to the planar substrate toward the fluid reservoir such that the flexible conduit fluidly connects the at least one channel to the fluid reservoir.