A multiplex PCR chip capable of simultaneously detecting multiple target genes and a multiplex PCR method using the same are proposed. More specifically, in the multiplex PCR chip and multiplex PCR method, after a plurality of spatially separated particle-forming grooves is formed in one or more reaction chambers and a probe in a solution state is injected into the particle-forming grooves, planar shapes of the particle-forming grooves are varied or shapes and patterns of particle holders respectively formed on inner surfaces of the particle-forming grooves are varied, and the probe including primers specifically hybridizing with sequences of different nucleic acid molecules is injected into the particle-forming grooves, whereby simultaneous multiplex detection is possible by allowing multiple target genes to be detected on the basis of positions and shapes of the probe particles and the shapes and patterns of the particle holders respectively formed inside of the probe particles.

A method for making a biochip structure, includes: providing a substrate and forming a plurality of biochips on a surface of the substrate; forming a carrier on a side of the substrate having the biochips, defining a plurality of through holes in the substrate from a side of the substrate away from the carrier; and filling conductive material in each of the through holes to connect one of the biochips. The carrier defines a plurality of openings. Each opening cooperates with substrate to form a micro-channel, and one of the biochips is exposed in the micro-channel.

An exemplary embodiment of the present disclosure provides a fluidic device comprising a substrate, an applicator, and a spacer. The substrate can comprise a plurality of wells. The applicator can be used for manipulating a biological substance in at least a portion of the plurality of wells. The spacer can be positioned between the substrate and the applicator. The spacer can be configured to allow the applicator to apply the biological substance to at least a portion of the plurality of wells while maintaining a space between the substrate and the applicator.

An integrated package comprising a lab-on-chip (LOC) is disclosed. The LOC includes at least one integrated device having a membrane portion having a membrane opening; the membrane portion having a first side and a second side, the first side opposite the second side, a MEMS portion disposed on the first side of the membrane portion, the MEMS portion having a sharp member disposed on an actuator stage within a MEMS cavity, and a fluidic portion disposed on the second side of the membrane portion, the fluidic portion having a fluidic cavity for flowing a fluid medium within the fluidic portion; and a fluidic cap forming a surface of the fluidic portion of the LOC, the fluidic cap having a fluidic inlet and a fluidic outlet. The method of operating the LOC includes power to the at least one integrated device to capture one or more particles for interrogation.

The present invention relates to a multiplex slide plate for various types of assays. The slide plate may be pre-filled with special-formulated reagents in different reaction zones, and the reactions carry out independently in the reaction zones filled with special-formulated reagent.

A cell capture system including an array, an inlet manifold, and an outlet manifold. The array includes a plurality of parallel pores, each pore including a chamber and a pore channel, an inlet channel fluidly connected to the chambers of the pores; an outlet channel fluidly connected to the pore channels of the pores. The inlet manifold is fluidly connected to the inlet channel, and the outlet channel is fluidly connected to the outlet channel. A cell removal tool is also disclosed, wherein the cell removal tool is configured to remove a captured cell from a pore chamber.

The present disclosure relates to an integrated chip, which includes a cell enrichment region, a cell separation region and a cell capture region, wherein one end of the cell enrichment region is provided with an inlet, and the other end of the cell enrichment region is provided with a waste liquid outlet and an enriched liquid outlet; one end of the cell separation region is provided with a buffer solution inlet and an enriched liquid inlet , and the other end of the cell separation region is provided with an outlet; one end of the cell capture region is provided with an inlet, and the other end of the cell capture region is provided with a separated liquid outlet. Compared with the traditional technology, the chip can separate a target cell from a to-be-treated cell solution with a high efficiency, and capture the target cell in situ in a chip.

Enhanced composite liquid cell (CLC) devices and methods of using the same are provided. The devices find use in, among other applications, CLC mediated nucleic acid library generation protocols, e.g., for use in next generation sequencing applications.

Devices for detecting a particle in a fluid sample are provided. The device includes a segmented microfluidic conduit configured to carry a flow of a fluid sample, where the conduit includes one or more nodes and two or more sections, and a node is positioned between adjacent sections of the conduit. The device also includes a detector configured to detect a change in current through the conduit. Also provided are methods of using the devices as well as systems and kits that include the devices. The devices, systems and methods find use in a variety of different applications, including diagnostic assays.

Polymer hydrogels and methods for selective retrieval of microbial targets from microwells and other cell culture devices. The methods use semi-permeable, photodegradable hydrogel membranes that permit exchange of nutrients and waste products but seals motile bacteria and other microbes within microwells. Light exposure can be used to degrade the hydrogel membrane in a targeted manner and release the microbes from targeted microwells for further study.